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Salt Lake Potash #SO4 and Mitsubishi Enter MOU for Offtake Arrangement
Salt Lake Potash (SO4) is pleased to announce that the Company has today executed a Memorandum of Understanding (MOU) with Mitsubishi Australia Limited and Mitsubishi Corporation (Mitsubishi) for the first formal Offtake Agreement for the Goldfields Salt Lakes Project (GSLP).
The formal Offtake Agreement will provide Mitsubishi with sales and offtake rights for up to 50% of the Sulphate of Potash (SOP) production from a Demonstration Plant at the GSLP, for distribution into Asia and Oceania and potentially other markets. 
Salt Lake Potash is completing studies for construction of a Demonstration Plant producing up to 50,000tpa of high quality SOP, and plans to distribute production through a small number of global distribution partnerships.
The MOU is non-binding and sets out the key terms for a subsequent formal Offtake Agreement as the Demonstration Plant is developed. As well as quantities and target markets, the MOU’s other terms include:
- Market pricing and commission mechanisms;
- Specifications and delivery parameters;
- Mitsubishi to provide strategic advice on marketing within the region; and
- The parties to continue discussions regarding funding requirements for the GSLP.
Mitsubishi Australia Limited is a wholly owned subsidiary of Mitsubishi Corporation. Mitsubishi is one of the world’s largest trading and investment enterprises that develops and operates businesses across virtually every industry, including industrial finance, energy, metals, machinery, chemicals, and daily living essentials. Its current activities expand far beyond its traditional trading operations to include investments and business management in diverse fields including natural resources development, manufacturing of industrial goods, retail, new energy, infrastructure, finance and new technology-related businesses.
Salt Lake Potash CEO Matt Syme said “We are very pleased to have taken this important first step in establishing offtake and distribution channels for the Goldfields Salt Lakes Project. Our model of distribution partnerships is vital for what is essentially an export Project. Mitsubishi’s global pre-eminence in commodities trading and finance and longstanding involvement in Australian industry, give us great confidence that we can build a very cohesive and beneficial partnership over time. Their interest is a strong endorsement of the market outlook for SOP and also of our plans to supply these markets. We anticipate one or two more potential distribution agreements and we believe our patience in aiming for the very best channels and markets is the right approach.”
For further information please visit www.saltlakepotash.com.au or contact:
|
Matt Syme/Sam Cordin |
Salt Lake Potash Limited |
Tel: +61 8 9322 6322 |
|
Jo Battershill |
Salt Lake Potash Limited |
Tel: +44 (0) 20 7478 3900 |
|
Colin Aaronson/Richard Tonthat |
Grant Thornton UK LLP (Nominated Adviser) |
Tel: +44 (0) 20 7383 5100 |
|
Derrick Lee/Beth McKiernan |
Cenkos Securities plc (Joint Broker) |
Tel: +44 (0) 131 220 6939 |
|
Jerry Keen/Toby Gibbs
|
Shore Capital (Joint broker) |
Tel: +44 (0) 20 7468 7967
|
This information is provided by RNS
Specifications and delivery parameters;
Salt Lake Potash #SO4 – Exploration targets reveal World Class scale potential
Salt Lake Potash Limited (SLP or the Company) is pleased to announce results of an initial estimate of Exploration Targets for eight of the nine lakes comprising the Company’s Goldfields Salt Lakes Project (GSLP). The ninth lake, Lake Wells, already has a Mineral Resource reported in accordance with the JORC code.
The total “stored” Exploration Target for the GSLP is 290Mt – 458Mt of contained Sulphate of Potash (SOP) with an average SOP grade of 4.4 – 7.1kg/m3 (including Lake Wells’ Mineral Resource of 80-85Mt). On a “drainable” basis the total Exploration Target ranges from 26Mt – 153Mt of SOP. The total playa area of the lakes is approximately 3,312km2.
The potential quantity and grade of this Exploration Target is conceptual in nature. There has been insufficient exploration to estimate a Mineral Resource and it is uncertain if further exploration will result in the estimation of a Mineral Resource.
|
Area |
Average Grade (kg/m3) |
Stored (Mt) |
Drainable (Mt) |
||||
|
Lake |
(km2) |
SOP (min) |
SOP (max) |
SOP (min) |
SOP (max) |
SOP (min) |
SOP (max) |
|
Ballard |
626 |
3.5 |
4.7 |
42 |
53 |
3.1 |
18 |
|
Barlee |
350 |
1.9 |
4.3 |
10 |
21 |
0.8 |
8.1 |
|
Irwin |
306 |
4.8 |
8.1 |
25 |
43 |
1.9 |
15 |
|
Marmion |
339 |
3.0 |
5.1 |
20 |
34 |
1.6 |
11 |
|
Minigwal |
567 |
3.8 |
8.3 |
45 |
98 |
3.4 |
31 |
|
Noondie |
386 |
4.2 |
6.0 |
35 |
50 |
2.8 |
16 |
|
Raeside |
89 |
2.1 |
7.0 |
6 |
20 |
0.4 |
5.4 |
|
Way |
172 |
5.6 |
15.5 |
28 |
54 |
2.7 |
19 |
|
Wells |
477 |
8.7 |
8.8 |
801 |
851 |
92 |
292 |
|
Total |
3,312 |
4.4 |
7.1 |
290 |
458 |
26 |
153 |
1. Incorporating Lake Wells’ stored Mineral Resource Estimate previously reported.
2. Lake Wells Mineral stored Mineral Resource Estimate converted to drainable equivalent.
Table 1: GSLP Exploration Target
The combined resources and exploration targets in the GSLP comprise a globally significant Project in the SOP sector, potentially sustaining one of the world’s largest SOP production operations for many decades.
CEO Matt Syme commented “These initial exploration targets allow us for the first time to quantify the real scale of the long term opportunity at the Goldfields Salt Lakes Project. We have already made very substantial progress in revealing the outstanding potential at Lake Wells and these Exploration Targets illustrate how the broader Project has a multiple of that potential. This places the GSLP asset at the leading edge of world scale SOP development opportunities.”
The Company’s long term plan is to develop an integrated SOP operation, producing from a number (or all) of the lakes within the GSLP, after confirming the technical and commercial elements of the Project through construction and operation of a Demonstration Plant producing up to 50,000tpa of SOP.
The Company’s recent Memorandum of Understanding with Blackham Resources Limited (see ASX Announcement dated 12 March 2018) offers the potential for an expedited path to development at Lake Way, possibly the best site for a 50,000tpa Demonstration Plant in Australia.
The GSLP has a number of very important, favourable characteristics:
Ø Very large paleochannel hosted brine aquifers, with chemistry amenable to evaporation of salts for SOP production, extractable from both low cost trenches and deeper bores;
Ø Over 3,300km2 of playa surface, with in-situ clays suitable for low cost on-lake pond construction;
Ø Excellent evaporation conditions;
Ø Excellent access to transport, energy and other infrastructure in the major Goldfields mining district;
Ø Lowest quartile capex and opex potential based on the Lake Wells Scoping Study;
Ø Clear opportunity to reduce transport costs by developing lakes closer to infrastructure and by capturing economies of scale;
Ø Multi-lake production offers operational flexibility and protection from localised weather events;
Ø The very high level of technical validation already undertaken at Lake Wells substantially applies to the other lakes in the GSLP; and
Ø Potential co-product revenues, particularly where transport costs are lowest.
Salt Lake Potash will progressively explore the lakes in the portfolio with a view to estimating resources for each Lake, in parallel with the development of the Demonstration Plant. Exploration of the lakes will be prioritised based on likely transport costs, scale, permitting pathway and brine chemistry.
THE GOLDFIELDS SALT LAKES PROJECT
The nine lakes comprising the GSLP were selected for scale, potential brine volume, known hypersaline brine characteristics, and the potential for production from both shallow trenches and deeper paleochannel aquifer bores. Each has a large surface area, a flat and bare surface playa and proximity to the important transport and energy infrastructure and engineering expertise available in the Western Australian Goldfields.
The GSLP has a number of very important, favourable characteristics:
Paleochannel Hosted Brine Aquifers
The GSLP salt lakes are each part of typical Western Australian paleovalley environments. Ancient hydrological systems incised paleovalleys into Palaeozoic or older basement rocks, which were then infilled by Tertiary-aged sediments, typically comprising a coarse-grained fluvial basal sand, overlain by paleovalley clay with some coarser grained interbeds. The clay is overlain by recent Cainozoic material including lacustrine sediment, calcrete, evaporite and aeolian deposits.
There are two methods of extracting brine from aquifers. Firstly, low cost trenching from the surface aquifer and the secondly, extraction from the paleochannel basal aquifer via bores.
All the lakes in the GSLP offer very large paleochannel hosted brine aquifers, with brine chemistry amenable to evaporation of salts for SOP production.
Large Playa Surface
The lakes included in the GSLP have a surface area averaging 370km2 and totaling over 3,300km2. This large surface area and the occurrence of impermeable clays near the surface, provides the potential for constructing low cost, on-lake, unlined evaporation ponds.
As demonstrated at Lake Wells (refer to ASX Announcement dated 16 October 2017), this provides significant potential capex savings. The results from the evaporation pond trial at Lake Wells exceeded expectations and strongly validated SLP’s model for construction of on-lake, unlined evaporation ponds. Net seepage of 2.4mm per day in a test scale pond extrapolates to less than 0.125mm per day in a 400ha Demonstration Plant scale halite pond, a negligible inefficiency in the context of overall pond operations.
Preliminary excavation and sampling at Lakes Ballard, Irwin and Way also indicate the presence of clays amenable for pond construction near the lake surface.
Excellent Evaporation Conditions
The Goldfields has very favourable arid climatic conditions with annual Class A pan evaporation in the region around ~3,000mm per year. This compares favourably with other global brine projects currently in production.
Access to Transport, Energy and Other Infrastructure
The lakes of the GSLP are strategically located close to the regional transport and energy infrastructure corridor. Transport from site to port is the single largest cost factor for (export oriented) Australian salt lake SOP projects, and the GSLP has a considerable advantage in this regard, with excellent proximity to the Kalgoorlie-Leonora rail line and the Goldfields Highway. The Company has made substantial progress in understanding and optimising its transport proposition, with major economies of scale to be achieved as the production volume increases.
The table below sets out the straight-line and existing road distances to the nearest railhead for each lake.
|
Lake |
Railhead |
Straight-line Distance to Rail line |
Likely Road Haul Distance |
|
Lake Wells |
Malcolm |
270 |
318 |
|
Lake Way |
Leonora |
230 |
281 |
|
Lake Irwin |
Leonora |
85 |
170 |
|
Lake Ballard |
Menzies |
2 |
20 |
|
Lake Marmion |
Menzies |
20 |
47 |
|
Lake Minigwal |
Kookynie |
130 |
172 |
|
Lake Raeside |
Leonora |
20 |
20 |
|
Lake Noondie |
Leonora |
110 |
198 |
|
Lake Barlee |
Menzies |
130 |
133 |
|
Average |
111 |
151 |
Table 2: Transportation Distances of the GSLP
The Goldfields Gas Pipeline also intersects the GSLP, passing close to a number of lakes, offering potential energy cost savings.
Multi-Lake Production
There is substantial potential for integration, economies of scale, operating synergies and overhead sharing in the GSLP across a number of producing lakes.
There is also the possibility of some important elements of the SOP production process such as compaction, agglomeration and packaging being centralised, probably adjacent to rail loading facilities.
The flexibility of multi-lake production is also appealing for a natural production process which is subject to climate variability, where the operating risk of individual high rainfall events is diminished over a portfolio of production lakes.
Technical Validation Already Undertaken at Lake Wells
At Lake Wells, the Company has tested and verified all the major technical foundations for production of SOP from Lake Wells brine to a standard previously unseen in Australia under actual site conditions and across all seasons.
These key technical achievements at Lake Wells will have significant application across the other lakes in the GSLP, given the similar geology, brine chemistry and climate conditions.
Lowest Quartile Capex and Opex
The Scoping Study on Lake Wells released in August 2016 (see ASX announcement dated 29 August 2016) highlighted the outstanding potential economics of extracting hypersaline brine by trenches and bores for solar evaporation of salts and processing to produce premium SOP. The Scoping Study indicates Lake Wells would be firmly in the lowest cost quartile for any SOP Project in Australia and around the world, with relatively low transport costs being a major advantage.
|
Stage 1 |
Stage 2 |
|
|
Annual Production (tpa) – steady state |
200,000 |
400,000 |
|
Capital Cost * |
A$191m |
A$39m |
|
Operating Costs ** |
A$241/t |
A$185/t |
|
* Capital Costs based on an accuracy of -10%/+30% before contingencies and growth allowance but including EPCM. Stage 1 Capital Costs include most of the main capital items for 400,000tpa production. ** Operating Costs based on an accuracy of ±30% including transportation & handling (FOB Esperance) but before royalties and depreciation. |
||
Table 3: Lake Wells Scoping Study
Lake Way is likely to offer material economic advantages even over Lake Wells due to proximity and availability of transport and other infrastructure and potential cost saving with the Matilda-Wiluna Gold Operation.
Production of Valuable Co-Products
Brine modelling and evaporation testwork has demonstrated that Lakes Wells, Irwin, Ballard and Way can produce potassium and magnesium salts amenable to conversion to SOP and also potentially other valuable co-products.
Kieserite (MgSO4.H2O) and Epsom salts (MgSO4.7H2O) are valuable fertiliser products for both the domestic and export markets, with particular application in the tropical crop regions in South East Asia, South America and Africa.
While magnesium nutrients have lower market value than SOP, they are potentially valuable co-products, particularity where transport costs are lowest, for example Lakes Ballard and Marmion.
Exploration Targets for MgSO4.7H2O (Epsom Salt) were calculated at the each lake, except Lake Wells, as follows:
|
Stored (Mt) |
Drainable (Mt) |
Average Grade (kg/m3) |
||||
|
Lake |
MgSO4 (min) |
MgSO4 (max) |
MgSO4 (min) |
MgSO4 (max) |
MgSO4 (min) |
MgSO4 (max) |
|
Ballard |
667 |
949 |
51 |
320 |
58 |
82 |
|
Barlee |
158 |
431 |
13 |
163 |
31 |
84 |
|
Irwin |
145 |
304 |
11 |
106 |
27 |
57 |
|
Marmion |
355 |
712 |
27 |
235 |
53 |
107 |
|
Minigwal |
668 |
1,462 |
50 |
469 |
57 |
124 |
|
Noondie |
308 |
488 |
23 |
154 |
37 |
58 |
|
Raeside |
86 |
358 |
6 |
98 |
30 |
126 |
|
Way |
151 |
339 |
15 |
125 |
49 |
105 |
|
Total |
2,538 |
5,043 |
196 |
1,670 |
46 |
92 |
MgSO4 = the molar mass of MgSO4.7H20 based on a conversion ratio of 10.14 of Mg to MgSO4.7H2O.
Table 4: Magnesium Sulphate Exploration Target
The potential quantity and grade of this Exploration Target is conceptual in nature. There has been insufficient exploration to estimate a Mineral Resource and it is uncertain if further exploration will result in the estimation of a Mineral Resource.
APPENDIX 1 – EXPLORATION TARGET METHODOLOGY AND RESULTS
GSLP Exploration Targets:
Exploration Target calculated using Total Porosity:
|
Lake |
Playa Area |
Estimated |
Sediment Volume |
Brine Volume |
Average Potassium Concentration |
SOP Tonnage |
||
|
Km2 |
Km |
Mm3 |
Mm3 |
Lower Estimate |
Upper Estimate |
Lower Estimate |
Upper Estimate |
|
|
Ballard |
626 |
55 |
26,370 |
11,487 |
1.6 |
2.1 |
42 |
53 |
|
Barlee |
350 |
60 |
11,455 |
5,107 |
0.8 |
1.9 |
10 |
21 |
|
Irwin |
306 |
22 |
11,942 |
5,236 |
2.1 |
3.6 |
25 |
43 |
|
Marmion |
339 |
35 |
15,294 |
6,626 |
1.3 |
2.3 |
20 |
34 |
|
Minigwal |
567 |
100 |
27,166 |
11,716 |
1.7 |
3.7 |
45 |
98 |
|
Noondie |
386 |
75 |
19,412 |
8,345 |
1.9 |
2.7 |
35 |
50 |
|
Raeside |
89 |
35 |
6,775 |
2,844 |
0.9 |
3.1 |
6 |
20 |
|
Way |
172 |
25 |
8,044 |
3,475 |
3.6 |
7.0 |
28 |
54 |
|
Wells |
477 |
60 |
24,723 |
9,639 |
3.9 |
80 |
85 |
|
|
Total |
3,312 |
467 |
151,181 |
64,474 |
290 |
458 |
||
Table 5: Exploration Target calculated using Total Porosity
Exploration Target calculated using Drainable Porosity:
|
Lake |
Sediment Volume |
Weighted Average |
Brine Volume |
Average Potassium Concentration |
SOP Tonnage |
||||
|
Mm3 |
kg/m3 |
Mt |
|||||||
|
Mm3 |
Sy |
Sy |
Lower Estimate |
Upper Estimate |
Lower Estimate |
Upper Estimate |
Lower Estimate |
Upper Estimate |
|
|
Ballard |
26,370 |
0.03 |
0.15 |
882 |
3,913 |
1.6 |
2.1 |
3.1 |
18 |
|
Barlee |
11,455 |
0.04 |
0.17 |
404 |
1,931 |
0.8 |
1.9 |
0.8 |
8 |
|
Irwin |
11,942 |
0.03 |
0.15 |
408 |
1,844 |
2.1 |
3.6 |
1.9 |
15 |
|
Marmion |
15,294 |
0.03 |
0.14 |
501 |
2,192 |
1.3 |
2.3 |
1.6 |
11 |
|
Minigwal |
27,166 |
0.03 |
0.14 |
877 |
3,783 |
1.7 |
3.7 |
3.4 |
31 |
|
Noondie |
19,412 |
0.03 |
0.14 |
619 |
2,645 |
1.9 |
2.7 |
2.8 |
16 |
|
Raeside |
6,775 |
0.03 |
0.11 |
198 |
778 |
0.9 |
3.1 |
0.4 |
5 |
|
Way |
8,044 |
0.04 |
0.15 |
299 |
1,196 |
2.8 |
7.1 |
2.7 |
19 |
|
Wells2 |
24,723 |
0.04 |
0.14 |
1,074 |
3,355 |
3.9 |
9 |
29 |
|
|
Total |
151,181 |
0.03 |
0.14 |
5,262 |
21,637 |
26 |
153 |
||
1. Drainable Porosity was assigned to each geological unit per Table 9 Porosity Estimates. The volume weighted average value is presented here.
2. Incorporating Lake Wells’ total Mineral Resource Estimate previously reported.
Table 6: Exploration Target calculated using Drainable Porosity
The potential quantity and grade of this Exploration Target is conceptual in nature. There has been insufficient exploration to estimate a Mineral Resource and it is uncertain if further exploration will result in the estimation of a Mineral Resource.
The Company engaged an independent hydrogeological consultant with substantial salt lake brine expertise, Groundwater Science Pty Ltd, to complete the Exploration Targets for all the lakes in the GSLP.
Scope
The Exploration Target is a statement or estimate of the exploration potential of a mineral deposit in a defined geological setting where the statement of estimate, quotes as a range of tones and a range of grade (or Quality), relative to mineralisation for which there has been insufficient exploration to estimate a Mineral Resource. The potential quantity and grade is conceptual in nature and there has been insufficient exploration to estimate a Mineral Resource and it is uncertain if further exploration will result in the estimation of a Mineral Resource.
The Exploration Targets are reported in accordance with
• the JORC Code 2012,
• the draft Guidelines for Resource and Reserve Estimation for Lithium and Potash Brines, developed by the Australia Association of Mining and Exploration Companies (AMEC), and
• the Canadian Institute of Mining, Metallurgy and Petroleum (CIM) Best Practice Guidelines for Resource and Reserve Estimation for Lithium Brines.
A Mineral Resource Estimate for Lake Wells has been reported (refer to ASX Announcements dated 11 November 2015 and 22 February 2016), comprising a total of 85Mt SOP. This estimate was calculated as the total in-situ resource based on the total porosity of the brine host aquifer. The resource has been re-calculated for this study based on the estimates of drainable porosity that are detailed below. The aim is to provide an estimate of mineralisation that is comparable to the proposed Exploration Targets and collate an inventory of the entire GSLP project.
Data sources
An exploration target for each lake has been defined by review of:
· All historic exploration data that has been released for the tenement, including drilling and geophysics;
· All public geology and hydrogeology reports, maps and data;
· Company hydrogeological reports obtained from the Western Australia Department of Water and Environmental Regulation via freedom of information request;
· Surface brine samples from test pits; and
· Test Pits, test excavation, and geophysical survey, undertaken by SLP.
Geology
Each playa lake exhibits reasonably consistent Tertiary paleovalley morphology as described in detail by Bell et al. (2012)[1], Johnson et al. (1999)[2], and DeBroekert and Sandiford (2005)[3]. Paleovalleys are incised into the Palaeozoic or older basement rocks. These are then infilled by Tertiary-aged sediment typically comprising a coarse-grained fluvial Basal Sand overlain by Paleovalley Clay with some coarser grained interbeds. The clay is overlain by Cainozoic Alluvium, that includes lacustrine clay, calcrete, evaporite and aeolian deposits.
|
Geological Unit |
Inferred age |
Description |
Hydrogeological Attributes |
|
Lake surface and islands |
Recent |
Clay sediments with some sandy, evaporite and calcrete horizons containing variable abundance of evaporite minerals, particularly gypsum. |
Minor aquifer. Highly variable permeability and moderate drainable porosity. |
|
Alluvium |
Cainozoic |
Unconsolidated silt, sand and clay sediments. |
Minor aquifer. Moderate permeability and moderate drainable porosity |
|
Paleovalley clay |
Tertiary (Miocene) |
Stiff to plastic clay. Minor silt and sand interbeds |
Aquitard. Low permeability and low drainable porosity |
|
Basal sand |
Tertiary (Eocene) |
Typically fining upwards sequence of sand with silt, clay and lignitic interbeds. |
Major aquifer. High to moderate permeability and High to moderate drainable porosity |
Table 7: Geological Units
Geological Model
At each playa lake, the extent and thickness of each geological unit has been inferred from the available data. Differentiating each geological unit is important because each unit exhibits specific hydrogeological properties, permeability and drainable porosity as described below.
Area
The area of each playa lake was calculated by digitising the lake surface and removing area covered by islands. These areas are used to calculate the volume of the lake sediments. The extent of the brine body hosted by alluvium has been defined by the extent of the lake playa. Extension of the brine body beyond the lake playa edge in shallow sediment is possible but unsupported by data at this stage. Studies on other playa lakes have demonstrated that brine concentration quickly diminishes with distance from the playa edge. The mechanism for lower brine grade off the playa is understood to be dilution by rainfall infiltration and the absence of the intense evaporation that occurs on the playa surface.
The extent of the lower Paleovalley Clay and Basal Sand is based on the mapped distribution of paleovalleys across the Northern Goldfields by Johnson et al. (1999) and other studies. This has been used as the basis for determining paleovalley length. There has been additional geophysics undertaken at Lakes Ballard, Irwin and Marmion that provides a more accurate interpretation. At Lake Way, exploration drilling for the Mt Keith Borefield (AGC Woodward Clyde, 1992) has further confirmed the paleochannel extent and presence of the Basal Sand.
Thickness
Lake Sediments (Upper Alluvium)
The lake sediments are dominated by clay lacustrine deposits with abundant evaporite minerals, such as gypsum. The thickness of this unit is poorly resolved. An average thickness of 10m has been assumed. The 10m thickness of Lake sediments are also the maximum depth of dilution calculated beneath islands on the Playa Surface.
Alluvium
The alluvium comprises a mixed sequence of sheetwash, calcrete and aeolian deposits that underlie the lake sediments. It has been mapped by Johnson et al. (1999) as a channel fill deposit being similar in nature to that found in present-day outwash alluvial fans and minor creeks, and it extends and is present beyond the lake margins. The thickness is highly variable and is up to 60m thick in parts of the Raeside Paleovalley. An average thickness of 15m has been applied for the exploration target estimation.
Paleochannel Clay
The paleochannel clay is a stiff clay that confines the basal paleochannel sand. It has a variable thickness depending on whether a site is within a trunk (thicker) or tributary (thinner) paleovalley. The width is dependent on the basement material with wider channels in granitoid basement and narrower channels in greenstone lithologies. For the resource estimation, the thickness and width was determined based on nearby geological transects from Langford (1997) and Johnson et al. (1999), or other company drilling in the case of Lake Way.
Basal Sand
The basal sand is present in the deepest section of the paleovalley. It has a variable thickness with some sand sections being up to 40 m thick. The development of the sand is dependent on proximity to granitoid catchments with less sand thickness in catchments dominated by greenstone lithologies. As with the paleochannel clay, the thickness and width was determined based on nearby geological transects from Langford (1997) and Johnson et al. (1999), or other company drilling in the case of Lake Way. As an example, the conceptual model applied to a cross section at Lake Ballard developed by Langford (1997).
Brine Concentration
Brine concentration has been defined based on samples taken from test pits excavated into the Alluvium by SLP in 2017 (Appendix 3), and from historic drilling data where available. Minimum and Maximum values have been defined as the mean value +/- one standard deviation for sample sets of more than 10 samples. For sample sets of less than 10 samples, the minimum and maximum values have been used.
Where no brine chemistry data is available for the paleochannel sediments, brine concentration is assumed to be constant with depth. This assumption is supported by SLP’s experience at Lake Wells, other company reports for comparable paleochannel hosted brine in the Goldfields region, and work by Water and Rivers Commission and others. Proving this assumption by drilling and sampling is a priority for progressing evaluation of these targets.
Hydrogeological Attributes
Hydrogeological attributes assigned to each geological unit are summarised in Table 8.
The permeability of the Lake Sediments and Alluvium is expected to be variable. Permeability is dependent on the lithology of the sediment, development of evaporite minerals that can enhance permeability, and the development of calcrete minerals that can be extremely permeable.
Paleovalley Clay is a low permeability aquitard, brine held in this unit will not be drained by bores; however, some fraction of the brine stored in this unit might be accessed by leakage into the underlying basal sand.
Basal Sand is typically permeable, and brine is expected to be extracted by pumping from bores.
|
Geological Unit |
Hydrogeological Properties |
|
Lake Sediments |
Highly variable aquifer dependent on lithology and evaporite formation |
|
Alluvium |
Highly variable aquifer dependent on lithology and evaporite formation |
|
Paleovalley Clay |
Aquitard low permeability |
|
Basal Sand |
Aquifer high permeability |
Table 8: Hydrogeological Attributes
Porosity
Total porosity (Pt) relates to the volume of brine-filled pores contained within a unit volume of aquifer material. A fraction of this pore volume can by drained under gravity, this is described as the drainable porosity (or specific yield). The remaining fraction of the brine, which is held by surface tension and cannot be drained under gravity, is described as the specific retention (or un-drainable porosity).
A resource calculated as the product of drainable porosity is still not completely recoverable by gravity drainage to trenches or bores.
The reported mineral tonnage represents the brine with no recovery factor applied. It will not be possible to economically extract all the contained brine by pumping. The amount that can be extracted depends on many factors including the permeability of the sediments, adjacent groundwater composition, and the recharge dynamics of the aquifers. Brine projects typically recover a small fraction of the in-situ resource.
The total and drainable porosity of each geological unit has been estimated from lithology and benchmarking against other studies completed in comparable geological settings. A summary of the porosity assigned to each geological unit and the source of the estimates is presented in Table 9.
Benchmarking of the porosity applied in this study to other Australian salt lakes is presented in Table 10.
|
Geological Unit |
Total Porosity (%) |
Drainable Porosity (%) |
|
Lake Sediments |
0.46 |
0.04-0.2 |
|
Alluvium |
0.46 |
0.04-0.2 |
|
Paleovalley Clay |
0.4 |
0.01-0.05 |
|
Basal Sand |
0.4 |
0.1-0.2 |
Table 9: Porosity Estimates
|
Project |
||||||
|
WA Salt Lake 1 |
WA Salt Lake 2 |
WA Salt Lake 3 |
WA Salt Lake 4 |
GSLP |
||
|
Lake Sediments and Alluvium |
Total Porosity |
0.39 |
0.47 |
0.45 |
0.42-0.53 |
0.46 |
|
Drainable Porosity |
0.16 |
0.17 |
0.064 |
0.13-0.15 |
0.04-0.20 |
|
|
Clay |
Total Porosity |
0.47 |
0.5 |
– |
0.4 |
|
|
Drainable Porosity |
0.06 |
0.03 |
– |
0.01-0.05 |
||
|
Basal Sand |
Total Porosity |
0.4 |
0.4 |
– |
0.4 |
|
|
Drainable Porosity |
0.23 |
0.28 |
– |
0.1-0.20 |
||
Source: Company releases
Table 10: Porosity Benchmarks
Brine Hydrology and Water Balance
The brine hydrology and water balance of each playa lake is not yet defined at this early stage of project evaluation.
All the playa lakes are understood to flood intermittently following large rainfall events. This is based on information derived from a Geoscience Australia dataset that presents the frequency of inundation for the Australian continent based on analysis of Landsat TM images compiled since 1984 (GA, 2017)[4].
Flooding and direct infiltration of rainfall will recharge the lake sediments and contribute to the water balance of the brine system.
Pumping from confined paleochannels results in depressurisation of the paleochannel and subsequent slow leakage of groundwater from the overlying clay aquitard and lateral inflow from the adjacent weathered basement aquifer. Studies of long-term water supply abstraction from the Roe paleochannel suggest sustainable water yields of around 1GL/year per 10km of paleochannel are possible (Johnson, 2007)[5].
Neighbouring properties and temporal effects
Neighbouring properties and temporal effects have not been evaluated at this early stage of project development.
Treatment of Islands
Many of the salt lake playas contain islands on the playa surface. These islands generally comprise gypsiferous dunes and often exhibit some vegetation. They are more common in playas that are less frequently inundated Bowler, (1986)[6],presumably due to the erosion that occurs through wave action during periods of inundation. Research on other playas has shown that the brine beneath islands is typically diluted close to the surface. The mechanism is understood to be dilution by infiltration of rainfall through the islands, without the subsequent intense evaporation that occurs on the playa surface. This dilution effect diminishes with depth.
Shallow dilution beneath islands is considered in the Exploration Target estimate by defining the area occupied by islands and reducing brine concentration beneath the islands by a factor of 3 to a depth of 10m.
Mineralisation Extent
Mineralisation is calculated for the area beneath the salt lake playa and islands only. There is in-sufficient data at each site to infer continuity of the mineralisation beyond the playa extent.
A summary of the geological and hydrogeological data review undertaken at each playa lake is presented below.
APPENDIX 2 – GSLP GEOLOGICAL AND HYDROGEOLOGICAL DATA REVIEW
LAKE BALLARD
Previous Exploration
A large amount of historical exploration work has been undertaken surrounding Lake Ballard focusing on gold, nickel and uranium. There has been limited exploration on the lake surface with most exploration associated with uranium exploration in the upper 10 m. Soil sampling was undertaken on the lake, as well as a number of geophysical surveys and shallow drilling activities. The Company has reviewed multiple publicly available documents to provide an understanding of the geology and hydrogeology in the Lake Ballard paleodrainage.
Esso Australia (1977) completed ground-based gravity and seismic geophysical survey at western end of lake suggesting the presence of the palaeovalley. Uranerz Australia (1977) undertook airborne spectrometric and ground-based scintillometric surveys that was followed by auger drilling with 81 holes being completed to depths of up to 30 m bgl, which suggested the shallow alluvium is dominated by clay lithologies and some drill holes encountered the top of the paleochannel clay. Uranoz Ltd (2007) completed an airborne gravity survey over the eastern portion of Lake Ballard and eastward over the northern portion of Lake Marmion that broadly mapped the distribution of the paleochannel thalweg.
The most useful hydrogeological data relates groundwater exploration undertaken by the Geological Survey of Western Australia (GSWA) in 1987. Three north-south transects were drilled between Lake Ballard and Lake Marmion to explore for the main trunk paleodrainage that originates to the west of Lake Ballard and flows to the east beneath Lakes Marmion and Rebecca. Drill holes were cased where possible; however, most holes into the deeper paleochannel sediments couldn’t be cased owing to running sands. There are some drill sites with multiple bores and different screen intervals. A bore completion report details the drilling and bore construction (Nidagal, 1992), while a description of the hydrogeology between the two lakes is provided by Langford (1997).
Geology
The Lake Ballard paleodrainage is incised into the Archean basement and now in-filled with a mixed sedimentary sequence. There is a shallow sedimentary sequence comprising lake sediments overlying alluvium and colluvium that concealed a deeper sedimentary sequence of plastic clay and basal sand. The paleochannel sands occur only in the deepest portion.
The lake sediments are thin being less than 2 to 3 m thick, which tend to interfinger and grade downward into an upper, iron-stained sequence of alluvium and colluvium (up to 30 m thick). This upper sequence appears to be more clayey with noticeably less sandy horizons, when compared with other paleodrainages to the north. Between Lakes Ballard and Marmion, there are clay layers (up to 20 m thick) being separated by sandy clay to clayey sand beds.
The understanding of the deep stratigraphy in the paleovalley is limited to three drilling transects between Lakes Ballard and Marmion. The lower Tertiary-aged paleochannel sequence comprises dense plasticine clay (60m thick) and basal sands (up to 20m thick). In places, there are silcrete and sandy intervals within the plasticine clay providing a different stratigraphy to other paleodrainages.
Hydrogeology
The upper alluvium and colluvium is likely to be a minor aquifer associated with Lake Ballard, and in some places may form an aquitard. The basal sands are confined beneath the plastic clay and comprise fine to coarse-grained quartz sand, which forms a deeper aquifer being about 80m bgl in the west (estimated from ground-based geophysics) and about 110m bgl at the east of Lake Ballard. There has been no hydraulic testing of the shallow or deep aquifers at Lake Ballard; however, bore yields will be higher from the basal sands.
References
Esso Exploration and Production Australia Inc, 1977, 1999 Annual (Final) Report, Lake Ballard – Project 650, Mineral Claims 29/2988-3000, 29/3059 and 3060, 30/1249-1253, and 30/1266-1270 – unpublished report by Esso Australia, WAMEX A7536.
Langford, R., 1997, Hydrogeology of part of the Rebecca Palaeodrainage between Lake Ballard and Lake Marmion in the northeastern Goldfields of Western Australia, unpublished thesis for Master of Science (Applied Geology) at Curtin University.
Nidagal, V., 1992, Lake Ballard palaeodrainage groundwater investigation bore completion reports, Western Australia Geological Survey, Hydrogeology Report 1989/18, unpublished.
Uranerz Australia, 1977, Final Report covering the period from 10/12/1976 to 1/11/1977, Temporary Reserve No 6400H, unpublished report by Uranerz Australia, WAMEX A7330.
Uranoz Ltd, 2007, E59/599 – Goongarrie Project, Annual Technical Report, Period Ending December 18, 2007: Report compiled by Mark Gordon of Gondor Geoconsult Pty Ltd in December 2007, unpublished report for Uranoz Ltd, WAMEX A76810.
LAKE BARLEE
Previous Exploration
There has been limited exploration on the lake surface with most exploration associated with uranium exploration in the upper 10m. Soil sampling was undertaken on the lake, as well as a number of geophysical surveys and shallow drilling activities (Jervois Mining, 2013; Northern Uranium, 2008). The Company has reviewed multiple publicly available documents to provide an understanding of the geology and hydrogeology in the Lake Barlee paleodrainage.
Recent potash exploration work by Parkway Minerals on their tenements to the north of SLP tenements suggest the presence of a paleochannel feature (Parkway Minerals, 2017). There has been no drilling to date, but geophysics results indicate the combined depth of the paleovalley is about 75m (Parkway Minerals, 2017) being shallower than other paleodrainages as it is close to its headwaters.
Geology
There is little known about the stratigraphy in the Barlee Paleodrainage, as there has been no regional assessment undertaken. The paleovalley becomes shallower towards its headwaters in the west and south; as such it is possible that it is about 50m deep beneath the SLP tenements.
The paleodrainage is incised into the Archean basement and now in-filled with a mixed sedimentary sequence. Lake sediments are thin being less than 2 to 3m thick, which tend to interfinger and grade downward into an upper, iron-stained sequence of alluvium and colluvium (up to 30m thick). This shallow sedimentary sequence may conceal a deeper sedimentary sequence of plastic clay and basal sand. The presence of the paleochannel sands is unknown; however, if present they will occur in the deepest portion.
Hydrogeology
The upper alluvium and colluvium is likely to be a minor aquifer, and in some places may form an aquitard. Basal sands comprise fine to coarse-grained quartz sand may be confined beneath plastic clay and form a deeper aquifer. There has been no hydraulic testing of the shallow or deep aquifers at Lake Barlee; however, bore yields are likely to be higher from the basal sands.
References
Jervois Mining, 2013, Bulga Project, Final Surrender Report for period 6th September to 22nd May 2013, unpublished report, WAMEX A98133.
Northern Uranium, 2008, Annual Report for the Lake Barlee Project, Exploration Licence E77/1331, unpublished report, WAMEX A77895.
Parkway Minerals, 2017, Parkway Minerals announces seismic survey at Lake Barlee confirms deep paleo-channels, ASX announcement by Parkway Minerals, 17 October 2017.
LAKE IRWIN
Previous Exploration
Significant historical exploration work has been completed in the Lake Irwin area focusing on nickel and gold. This exploration work was largely undertaken in the basement lithologies surrounding the lake; however, there has been no substantial exploration on the lake.
The most useful stratigraphic and hydrogeological data relates to groundwater exploration undertaken by the Water and Rivers Commission (WRC) in 1997 and 1998. Three investigation transects were completed surrounding and across Lake Irwin. Transect B located across the middle of the lake failed to encounter the main trunk paleodrainage and is somewhat inconclusive. Transect C in the northwest encountered a palaeotributary with basal sand between 80 and 90 m bgl. Transect D located to the north of the lake encountered the basal sand between 110 and 140 m bgl. A bore completion report details the drilling and bore construction (Johnson et al., 1998), while a regional description of the hydrogeology is provided by Johnson et al. (1999).
Geology
The Carey paleodrainage, passing beneath Lake Irwin, is incised into the Archean basement and now in-filled with a mixed sedimentary sequence. There is a shallow sedimentary sequence comprising lake sediments overlying alluvium and colluvium that concealed a deeper sedimentary sequence of plastic clay and basal sand. The paleochannel sands occur only in the deepest portion.
The stratigraphy comprises thin lake sediments overlying an upper interbedded sequence of alluvium and colluvium (30m thick), and a lower Tertiary-aged paleochannel sequence of dense plasticine clay (50 to 60m) and basal sands (20 to 30m thick) that is surrounded by Archaean granite and greenstone basement.
Hydrogeology
The upper alluvium and colluvium is considered a minor aquifer owing to the fine-grained nature of the sediments and lack of thick sandy / gravel horizons. This aquifer is present beneath the entire lake surface. Direct hydraulic testing is limited; however, bore yields are likely to be low in the order of 1 to 2 L/sec and up to 5 L/sec in some cases. It is utilised by the pastoral industry for stock watering with bores and wells.
The deeper paleochannel sand is an important regional aquifer that is widely developed by the mining industry for meeting process water requirements. The thalweg of the trunk paleochannel appears to be about 1 to 2 km northeast of the lake, and only paleotributaries on the western side are present the current lake surface. In these paleotributaries, there are two production borefields (Charlie Well and Greymare) operated by Minara Resources’ Murrin Murrin operation. Long-term bore yields are commonly between 10 and 15 L/sec with up to 20 L/sec in the thickest thalweg sections.
References
Johnson, S., Mohsenzadeh, H., Yesterener, C., and Koomberi, H., 1998, Northern Goldfields regional groundwater assessment bore completion reports: Western Australia Water and Rivers Commission, Hydrogeology Report 107, unpublished.
Johnson, S., Commander, D., and O’Boy, C., 1999, Groundwater resources of the Northern Goldfields, Western Australia: Western Australia Water and Rivers Commission, Hydrogeological Record Series, Report HG2, 57p.
LAKE MARMION
Previous Exploration
A large amount of historical exploration work has been undertaken surrounding Lake Marmion focusing on gold, nickel and uranium. There has been limited exploration on the lake surface with most exploration associated with uranium exploration in the upper 10m. The Company has reviewed multiple publicly available documents to provide an understanding of the geology and hydrogeology in the paleodrainage beneath Lake Marmion.
Reports from previous tenement holders detailing mineral exploration programs provided useful data on the location of the paleochannel, and thickness / nature of the lake sediments. There have been a range of exploration activities including wide-spaced gravity surveys and some drilling at the western and eastern lake margins.
There have been several gravity surveys across the lake that have provided an understanding of the distribution of the paleochannel. The most recent surveys by Uranoz Ltd (2007a, b and c), Nickleore Ltd (2008) and Siburan Resources (2011a, b, c and 2012) suggest that the main trunk drainage takes a meandering path beneath the northern parts of the lake that merges with a large palaeotributary from the south.
Geology
There have been no regional studies on the Ballard-Marmion-Rebecca Paleodrainage – unlike the paleodrainages to the north (Johnson et al., 1999) and to the south (Commander et al., 1992). Despite this, there is high level of confidence that the main trunk drainage traverses the northern portion of the lake from Lake Ballard to Boomerang Lake / Lake Rebecca in the east, and there is also a large paleotributary from the south. The stratigraphy seems to broadly align with other paleodrainages in the northern Goldfields.
Lake sediments are probably thin being less than 2 to 3m thick, which tend to interfinger and grade downward into an upper, iron-stained sequence of alluvium and colluvium (up to 30m thick). This upper sequence may be more clayey with noticeably less sandy horizons, when compared with other paleodrainages to the north. Between Lakes Ballard and Marmion, there are clay layers (up to 20m thick) being separated by sandy clay to clayey sand beds.
The understanding of the deep stratigraphy is based on the drilling undertaken at the lake margins. In the northwest, one incomplete and shallow drilling transect was completed by AFMECO (1978 a and b) and three drilling transects were completed by the GSWA between Lakes Ballard and Marmion with detailed lithological descriptions in the bore completion reports (Nidagal, 1992) and interpreted stratigraphy for each transect (Langford, 1997). This drilling suggests a total thickness of about 80m with 20m of alluvium / colluvium overlying 45m of plasticine clay and 15m of basal sands. There are silcrete and sandy intervals at the base of the alluvium / colluvium and throughout the plasticine clay that provides a different stratigraphy to other paleodrainages.
Hydrogeology
The upper alluvium and colluvium is considered a minor aquifer owing to the dominance of clay lithologies and lack of thick sandy / gravel horizons. It is present beneath the entire lake surface. There has been no direct hydraulic testing with bore yields to be very low, less than 1 L/sec. In places, discrete bodies of calcrete are present that form localised aquifers; however, these bodies are less common near Menzies when compared with areas to the north. Groundwater resources in this shallow aquifer will be more likely accessed via leakage rather than direct abstraction.
The deeper paleochannel sand is an important regional aquifer that is widely developed by the mining industry to the north; however, there has been no utilisation in the vicinity of Lake Marmion. Long-term bore yields are commonly between 10 and 15 L/sec with up to 20 L/sec in the thickest thalweg sections.
References
AFMECO, 1978a, Yilgarn Drainage, Temporary Reserve 6402H, West Lake Marmion, Annual Report, Report WA 275F, February 1978, unpublished report, WAMEX 7573.
AFMECO, 1978b, Yilgarn Drainage, Temporary Reserve 6402H, West Lake Marmion, Final Report, Report WA 275F, July 1978, unpublished report, WAMEX 7945.
Commander, D.P., Kern, A.M. and Smith, R.A., 1992, Hydrogeology of the Tertiary Palaechannels in the Kalgoorlie Region (Roe Palaeodrainage): Western Australia Geological Survey, Record 1991/10.
Johnson, S., Commander, D., and O’Boy, C., 1999, Groundwater resources of the Northern Goldfields, Western Australia: Western Australia Water and Rivers Commission, Hydrogeological Record Series, Report HG2, 57p.
Langford, R., 1997, Hydrogeology of part of the Rebecca Palaeodrainage between Lake Ballard and Lake Marmion in the northeastern Goldfields of Western Australia, unpublished thesis for Master of Science (Applied Geology) at Curtin University.
Nickleore Ltd., 2008, E29/634 (Lake Marmion), 2008 Annual Report, 12 April 2007 to 11 April 2008, unpublished report, WAMEX 79044.
Nidagal, V., 1992, Lake Ballard palaeodrainage groundwater investigation bore completion reports, Western Australia Geological Survey, Hydrogeology Report 1989/18, unpublished.
Siburan Resources, 2011a, Lake Marmion Project, Annual Report, Exploration Licence E29/756, Western Australia, Reporting period 19 August 2010 to 18 August 2011, unpublished report, WAMEX 91660.
Siburan Resources, 2011b, Lake Marmion Project, Annual Report, Exploration Licence E29/757, Western Australia, Reporting period 18 November 2010 to 17 November 2011, unpublished report, WAMEX 92276.
Siburan Resources, 2011c, Gravity surveys outline new uranium prospective paleochannels at Lake Marmion Project, ASX announcement.
Siburan Resources, 2012, Lake Marmion Project, Annual Report, Exploration Licences E29/637, E29/756-757, E29/773, E29/778-780, E29/782, E31/939-940, E31/976-977, Reporting period 5 July 2011 to 4 July 2012, unpublished report, WAMEX 95065.
Uranoz Ltd., 2007a, Goongarrie Project, E59/598, Annual Technical Report, Period Ending November 14, 2007: Report prepared by Mark Gordon of Gondor Geoconsult Pty Ltd in December 2007, unpublished report, WAMEX 76809.
Uranoz Ltd., 2007b, Goongarrie Project, E59/599, Annual Technical Report, Period Ending December 18, 2007: Report prepared by Mark Gordon of Gondor Geoconsult Pty Ltd in December 2007, unpublished report, WAMEX 76810.
Uranoz Ltd., 2007c, Goongarrie Project, E59/600, Annual Technical Report, Period Ending December 18, 2007: Report prepared by Mark Gordon of Gondor Geoconsult Pty Ltd in December 2007, unpublished report, WAMEX 76811.
LAKE MINIGWAL
Previous Exploration
A large amount of historical exploration work has been undertaken in the area to the north of Lake Minigwal focusing on gold, nickel and uranium. The Company has reviewed multiple publicly available documents to develop an understanding of the geology and hydrogeology in the paleodrainage beneath the lake itself.
Mineral exploration has been undertaken surrounding the lake margins with minimal activity on or beneath the lake surface. There has been some drilling near the eastern portion of the lake (Uranerz, 1983); however, there was no reporting of lithology in these drill holes. Uranerz Pty Ltd (1987) focused on a tributary near Jasper Hill that flows in Lake Minigwal with a drill hole encountering shallow paleochannel sediments. An AEM (airborne electromagnetic) survey has been undertaken over the project area by Camuco Pty Ltd (2008): however, there were issues with near-surface conductivity masking. It was concluded that there is limited data from geophysical surveys and drilling activities that contribute to paleochannel interpretation at Lake Minigwal.
Geology
There is limited understanding of the deep stratigraphy beneath Lake Minigwal. In the available dataset, there are no drill holes that fully penetrate the Tertiary sequence with the deepest holes being about 60m bgl that were ceased in paleochannel clay. Granny Smith Mines (1999) noted that there are 120m deep paleochannels beneath Lake Carey near Wallaby deposit and it is assumed that this is the same paleochannel beneath Lake Minigwal.
Beneath 20 to 30m of alluvium and colluvium, there is a Tertiary-aged paleochannel sequence comprising dense plasticine clay (50 to 60m) and basal sands (10 to 20m thick) that are incised into the Archaean granite and greenstone basement. In places, there may be silcrete and sandy intervals within the plasticine clay. The basal sands are commonly fine to coarse-grained sand.
Hydrogeology
The upper alluvium and colluvium is considered a minor aquifer, which is present beneath the entire lake surface. There has been no direct hydraulic testing with bore yields to be low, less than 3 L/sec. In places, there may be discrete bodies of calcrete that form localised aquifers. Groundwater resources in this shallow aquifer may be directly abstracted from sandy intervals, but more likely via downward leakage.
The deeper paleochannel sand is an important regional aquifer that is widely developed by the mining industry to the north, in particular Granny Smith Mines at Lake Carey. Production bores are screened in the permeable basal sand and gravels. Long-term bore yields are commonly between 10 and 15 L/sec with up to 20 L/sec in the thickest thalweg sections
References
Camuco Pty Ltd, 2008, Annual Report for the Minigwal Project comprising ELs 39/1185, 39/1186, 39/1187, unpublished report, WAMEX A77594.
Granny Smith Mines, 1999, Lake Carey Project, E38/447, E38/448, E38/457, E39/387, E39/389 & E39/483, Mount Margaret Mineral Field, Western Australia, Sixth Annual Report on Exploration, Period ending 30th June 1999, Ref: M7959, unpublished report, WAMEX A59288.
Uranerz Pty Ltd, 1983, Final report on Exploration Licence 38/13, Rason Lake Area, Western Australia, Covering the Period 30 March 1983 to 4 November 1983, unpublished report, WAMEX A12985.
Uranerz Pty Ltd, 1987, Surrender Report on Exploration Licence 39/87, Lake Minigwal, Western Australia, Covering the period 23 March 1986 to 22 March 1987, unpublished report, WAMEX A20809.
LAKE NOONDIE
Previous Exploration
Previous diamond, gold and uranium exploration has been conducted in the vicinity of Lake Noondie. There has been limited exploration on the lake surface with most exploration associated with uranium exploration in the upper 10m. Soil sampling was undertaken on the lake, as well as a number of geophysical surveys and shallow drilling activities (Hemisphere, 2010, 2011; Mindax, 2008). The Company has reviewed multiple publicly available documents to provide an understanding of the geology and hydrogeology in the Lake Noondie paleodrainage.
Geology
There is little known about the stratigraphy in the Noondie Paleodrainage, as there have been no regional studies unlike the paleodrainages to the east (Johnson et al., 1999). The closest drill transect (Transect R) completed by the Water and River Commission (Johnson et al., 1999) is about 40km to the east. This drilling suggests the presence of a full paleochannel stratigraphy with a combined thickness of 130m.
The paleodrainage is incised into the Archean basement and now in-filled with a mixed sedimentary sequence. Lake sediments are thin being less than 2 to 3m thick, which tend to interfinger and grade downward into an upper, iron-stained sequence of alluvium and colluvium (up to 30m thick). This shallow sedimentary sequence conceals a deeper sequence of plastic clay and basal sand. The paleochannel sands will occur in the deepest portion and may be 20 to 30m thick.
Hydrogeology
The upper alluvium and colluvium is likely to be a minor aquifer associated with Lake Noondie. Basal sands comprise fine to coarse-grained quartz sand that are confined beneath plastic clay and form a deeper aquifer. There has been no hydraulic testing of the shallow or deep aquifers at Lake Noondie; however, bore yields will be higher from the basal sands.
References
Hemisphere Resources Ltd., 2010, Combined reporting group C61/2009, Bulga Downs Project, Exploration Licences E57/720, E57/721, E57/722, E57/762, E57/763, E57/781 and E57/782, Western Australia, Annual Report for the year ended 13 April 2010, unpublished report, WAMEX A87235.
Hemisphere Resources Ltd., 2011, Combined reporting group C61/2009, Bulga Downs Project, Exploration Licences E57/720, E57/721, E57/722, E57/762, E57/763, E57/781 and E57/782, Western Australia, Annual Report for the year ended 13 April 2011, unpublished report, WAMEX A90598.
Johnson, S., Commander, D., and O’Boy, C., 1999, Groundwater resources of the Northern Goldfields, Western Australia: Western Australia Water and Rivers Commission, Hydrogeological Record Series, Report HG2, 57p.
Mindax Ltd, 2008, Lake Noondie Project, Combined Annual Report for Exploration Licenses E57/602 (Lake Noondie West), E57/603 (Lake Noondie East) and E57/619 (Bill Well), Black Range District, East Murchison Mineral Field for the period 1st January 2007 and 31st December 2007, unpublished report, WAMEX A77744.
LAKE RAESIDE
Previous Exploration
A large amount of historical exploration work has been undertaken in the vicinity of Lake Raeside focusing on gold, limestone, nickel and uranium. There has been limited exploration on the lake surface with most exploration associated with limestone and uranium exploration in the upper 10m at the lake margins. Soil sampling was undertaken on the lake, as well as a number of geophysical surveys and shallow drilling activities. The Company has reviewed multiple publicly available documents to develop an understanding of the geology and hydrogeology in the paleodrainage beneath the lake itself.
The Water and Rivers Commission completed a regional groundwater resource assessment of the paleodrainages in the Northern Goldfields in 1997 and 1998. As part of this assessment, a drilling transect (Transect Q) was installed about 5 km north of Lake Raeside along the Ida Valley Road that encountered a full paleochannel stratigraphy with a combined thickness of 130 m (Johnson et al., 1999).
Geology
The paleodrainage is incised into the Archean basement and now in-filled with a mixed sedimentary sequence. Lake sediments are thin being less than 2 to 3 m thick, which tend to interfinger and grade downward into an upper, iron-stained sequence of alluvium and colluvium (up to 30 m thick). This shallow sedimentary sequence conceals a deeper sequence of plastic clay and basal sand. The paleochannel sands occur in the deepest portion, may be 20 to 30 m thick, and are present beneath the current lake surface
Hydrogeology
The upper alluvium and colluvium is likely to be a minor aquifer, and in some places may form an aquitard. The presence of calcrete at the margins suggests that there may be calcrete aquifer horizons within the upper 10 m. Beneath the plastic clay, basal sands comprise fine to coarse-grained quartz sand that forms a potential deeper aquifer. There has been no hydraulic testing of the shallow or deep aquifers at Lake Raeside; however, bore yields will be higher from the basal sands.
References
Johnson, S., Commander, D., and O’Boy, C., 1999, Groundwater resources of the Northern Goldfields, Western Australia: Western Australia Water and Rivers Commission, Hydrogeological Record Series, Report HG2, 57p.
LAKE WAY
Previous Exploration
Significant historical exploration work has been completed in the Lake Way area focusing on nickel, gold and uranium. The Company has reviewed multiple publicly available documents including relevant information on the Lake Way’s hydrogeology and geology.
Groundwater exploration was undertaken in the early 1990s by AGC Woodward Clyde to locate and secure a process water supply for WMC Resources Limited’s Mt Keith nickel operation. There was a wide and extensive program of exploration over 40km of paleodrainage that focused on both the shallow alluvium and deeper paleochannel aquifers.
The comprehensive drilling program comprised 64 air-core drill holes totalling 4,336m and five test production bores (two of which were within SLP’s exploration licences). The aquifers identified were a deep paleochannel sand unit encountered down the length of the Lake Way investigation area and a shallow mixed alluvial aquifer from surface to a depth of approximately 30m.
Geology
The Lake Way drainage is incised into the Archean basement and now in-filled with a mixed sedimentary sequence, the paleochannel sands occurring only in the deepest portion. The mixed sediments include sand, silts and clays of lacustrine, aeolin, fluvial and colluvial depositional origins. The surficial deposits also include chemical sediments comprising calcrete, silcrete and ferricrete. These sediments provide a potential reservoir for large quantities of groundwater.
The deep paleochannel sand aquifer is confined beneath plasticine clay up to 70m thick. The sand comprises medium to coarse grained quartz grains with little clay – it is approximately 30m thick and from 400m to 900m in width.
Hydrogeology
The shallow aquifer comprises a mixture of alluvium, colluvium and lake sediments extending beyond the lake playa and continuing downstream. Five test production bores were developed, of which two are within SLP’s tenements. CRT bore yields ranged from 520 kL/day up to 840 kL/day in permeable coarse-grained sand.
References
AGC Woodward-Clyde Pty Ltd, 1992, Mt Keith Process Water Supply, Lake Way Area, Volume 1, Contained within WMC Resources, Partial Surrender Report for the period 8 December 1992 to 7 December 1995, unpublished report, WAMEX A48586.
Tenements
The GSLP tenements are detailed in the Table below:
|
Project |
Status |
License Number |
Area (km2) |
Term |
Grant Date |
Date of First Relinquish-ment |
Interest |
||||||
|
Western Australia |
|||||||||||||
|
Lake Wells |
|||||||||||||
|
Central |
Granted |
E38/2710 |
192.2 |
5 years |
05-Sep-12 |
4-Sep-17 |
100% |
||||||
|
South |
Granted |
E38/2821 |
131.5 |
5 years |
19-Nov-13 |
18-Nov-18 |
100% |
||||||
|
North |
Granted |
E38/2824 |
198.2 |
5 years |
04-Nov-13 |
3-Nov-18 |
100% |
||||||
|
Outer East |
Granted |
E38/3055 |
298.8 |
5 years |
16-Oct-15 |
16-Oct-20 |
100% |
||||||
|
Single Block |
Granted |
E38/3056 |
3.0 |
5 years |
16-Oct-15 |
16-Oct-20 |
100% |
||||||
|
Outer West |
Granted |
E38/3057 |
301.9 |
5 years |
16-Oct-15 |
16-Oct-20 |
100% |
||||||
|
North West |
Granted |
E38/3124 |
39.0 |
5 years |
30-Nov-16 |
29-Nov-21 |
100% |
||||||
|
West |
Granted |
L38/262 |
113.0 |
20 years |
3-Feb-17 |
2-Feb-38 |
100% |
||||||
|
East |
Granted |
L38/263 |
28.6 |
20 years |
3-Feb-17 |
2-Feb-38 |
100% |
||||||
|
South West |
Granted |
L38/264 |
32.6 |
20 years |
3-Feb-17 |
2-Feb-38 |
100% |
||||||
|
South |
Application |
L38/287 |
95.8 |
– |
– |
– |
100% |
||||||
|
South Western |
Granted |
E38/3247 |
350.3 |
5 years |
25-Jan-18 |
24-Jan-23 |
100% |
||||||
|
South |
Application |
M38/1278 |
87.47 |
– |
– |
– |
100% |
||||||
|
Lake Ballard |
|||||||||||||
|
West |
Granted |
E29/912 |
607.0 |
5 years |
10-Apr-15 |
10-Apr-20 |
100% |
||||||
|
East |
Granted |
E29/913 |
73.2 |
5 years |
10-Apr-15 |
10-Apr-20 |
100% |
||||||
|
North |
Granted |
E29/948 |
94.5 |
5 years |
22-Sep-15 |
21-Sep-20 |
100% |
||||||
|
South |
Granted |
E29/958 |
30.0 |
5 years |
20-Jan-16 |
19-Jan-21 |
100% |
||||||
|
South East |
Granted |
E29/1011 |
68.2 |
5 years |
11-Aug-17 |
10-Aug-22 |
100% |
||||||
|
South East |
Granted |
E29/1020 |
9.3 |
5 years |
21-Feb-18 |
20-Feb-23 |
100% |
||||||
|
South East |
Granted |
E29/1021 |
27.9 |
5 years |
21-Feb-18 |
20-Feb-23 |
100% |
||||||
|
South East |
Granted |
E29/1022 |
43.4 |
5 years |
21-Feb-18 |
20-Feb-23 |
100% |
||||||
|
Lake Irwin |
|||||||||||||
|
West |
Granted |
E37/1233 |
203.0 |
5 years |
08-Mar-16 |
07-Mar-21 |
100% |
||||||
|
Central |
Granted |
E39/1892 |
203.0 |
5 years |
23-Mar-16 |
22-Mar-21 |
100% |
||||||
|
East |
Granted |
E38/3087 |
139.2 |
5 years |
23-Mar-16 |
22-Mar-21 |
100% |
||||||
|
North |
Granted |
E37/1261 |
107.3 |
5 years |
14-Oct-16 |
13-Oct-21 |
100% |
||||||
|
Central East |
Granted |
E38/3113 |
203.0 |
5 years |
14-Oct-16 |
13-Oct-21 |
100% |
||||||
|
South |
Granted |
E39/1955 |
118.9 |
5 years |
14-Oct-16 |
13-Oct-21 |
100% |
||||||
|
North West |
Application |
E37/1260 |
203.0 |
– |
– |
– |
100% |
||||||
|
South West |
Application |
E39/1956 |
110.2 |
– |
– |
– |
100% |
||||||
|
Lake Minigwal |
|||||||||||||
|
West |
Granted |
E39/1893 |
246.2 |
5 years |
01-Apr-16 |
31-Mar-21 |
100% |
||||||
|
East |
Granted |
E39/1894 |
158.1 |
5 years |
01-Apr-16 |
31-Mar-21 |
100% |
||||||
|
Central |
Granted |
E39/1962 |
369.0 |
5 years |
8-Nov-16 |
7-Nov-21 |
100% |
||||||
|
Central East |
Granted |
E39/1963 |
93.0 |
5 years |
8-Nov-16 |
7-Nov-21 |
100% |
||||||
|
South |
Granted |
E39/1964 |
99.0 |
5 years |
8-Nov-16 |
7-Nov-21 |
100% |
||||||
|
South West |
Application |
E39/1965 |
89.9 |
– |
– |
– |
100% |
||||||
|
Lake Way |
|||||||||||||
|
Central |
Granted |
E53/1878 |
217.0 |
5 years |
12-Oct-16 |
11-Oct-21 |
100% |
||||||
|
South |
Application |
E53/1897 |
77.5 |
– |
– |
– |
100% |
||||||
|
Lake Marmion |
|||||||||||||
|
North |
Granted |
E29/1000 |
167.4 |
5 years |
03-Apr-17 |
02-Apr-22 |
100% |
||||||
|
Central |
Granted |
E29/1001 |
204.6 |
5 years |
03-Apr-17 |
02-Apr-22 |
100% |
||||||
|
South |
Granted |
E29/1002 |
186.0 |
5 years |
15-Aug-17 |
14-Aug-22 |
100% |
||||||
|
West |
Granted |
E29/1005 |
68.2 |
5 years |
11-Jul-17 |
10-Jul-22 |
100% |
||||||
|
Lake Noondie |
|||||||||||||
|
North |
Application |
E57/1062 |
217.0 |
– |
– |
– |
100% |
||||||
|
Central |
Application |
E57/1063 |
217.0 |
– |
– |
– |
100% |
||||||
|
South |
Application |
E57/1064 |
55.8 |
– |
– |
– |
100% |
||||||
|
West |
Application |
E57/1065 |
120.9 |
– |
– |
– |
100% |
||||||
|
East |
Application |
E36/932 |
108.5 |
– |
– |
– |
100% |
||||||
|
Lake Barlee |
|||||||||||||
|
North |
Application |
E49/495 |
217.0 |
– |
– |
– |
100% |
||||||
|
Central |
Granted |
E49/496 |
220.1 |
5 years |
17-Dec-17 |
16-Dec-22 |
100% |
||||||
|
South |
Granted |
E77/2441 |
173.6 |
5 years |
09-Oct-17 |
08-Oct-22 |
100% |
||||||
|
Lake Raeside |
|||||||||||||
|
North |
Application |
E37/1305 |
155.0 |
– |
– |
– |
100% |
||||||
|
Northern Territory |
|||||||||||||
|
Lake Lewis |
|||||||||||||
|
South |
Granted |
EL 29787 |
146.4 |
6 years |
08-Jul-13 |
7-Jul-19 |
100% |
||||||
|
North |
Granted |
EL 29903 |
125.1 |
6 years |
21-Feb-14 |
20-Feb-19 |
100% |
||||||
Competent Persons Statement
The information in this report that relates to Exploration Results, Exploration Targets or Mineral Resources is based on information compiled by Mr Ben Jeuken, who is a member Australian Institute of Mining and Metallurgy. Mr Jeuken is employed by Groundwater Science Pty Ltd, an independent consulting company. Mr Jeuken has sufficient experience, which is relevant to the style of mineralisation and type of deposit under consideration and to the activity, which he is undertaking to qualify as a Competent Person as defined in the 2012 Edition of the ‘Australasian Code for Reporting of Exploration Results, Mineral Resources and Ore Reserves’. Mr Jeuken consents to the inclusion in the report of the matters based on his information in the form and context in which it appears.
Forward Looking Statements
This announcement may include forward-looking statements. These forward-looking statements are based on Salt Lake’s expectations and beliefs concerning future events. Forward looking statements are necessarily subject to risks, uncertainties and other factors, many of which are outside the control of Salt Lake, which could cause actual results to differ materially from such statements. Salt Lake makes no undertaking to subsequently update or revise the forward-looking statements made in this announcement, to reflect the circumstances or events after the date of that announcement.
APPENDIX 2A – LAKE RAESIDE BRINE CHEMISTRY ANALYSIS
|
HOLE ID |
East |
North |
From (m) |
To (m) |
K (mg/L) |
Cl (mg/L) |
Na (mg/L) |
Ca (mg/L) |
Mg (mg/L) |
SO4 (mg/L) |
TDS (g/L) |
|
S700001 |
315501 |
6807912 |
0 |
1 |
2,270 |
138,200 |
82,000 |
1,020 |
5,420 |
10400 |
241 |
|
S700005 |
311513 |
6809765 |
0 |
1 |
1,440 |
73,000 |
44,000 |
1,500 |
3,390 |
8400 |
133 |
|
S700007 |
307959 |
6811061 |
0 |
1 |
2,180 |
115,350 |
68,700 |
1,060 |
5,330 |
11500 |
208 |
|
S700011 |
300035 |
6813662 |
0 |
1 |
2,240 |
149,850 |
87,900 |
603 |
8,690 |
17600 |
273 |
|
S700013 |
278641 |
6810996 |
0 |
1 |
3,140 |
167,950 |
96,900 |
409 |
12,400 |
27400 |
317 |
|
S700015 |
281725 |
6810666 |
0 |
1 |
950 |
55,550 |
34,100 |
600 |
3,130 |
8730 |
104 |
|
S700017 |
287751 |
6812747 |
0 |
1 |
2,230 |
124,500 |
74,100 |
789 |
6,510 |
15400 |
228 |
APPENDIX 2B – LAKE NOONDIE BRINE CHEMISTRY ANALYSIS
|
HOLE ID |
East |
North |
From (m) |
To (m) |
K (mg/L) |
Cl (mg/L) |
Na (mg/L) |
Ca (mg/L) |
Mg (mg/L) |
SO4 (mg/L) |
TDS (g/L) |
|
N700004 |
713808 |
6828889 |
0 |
1 |
2,630 |
131,000 |
78,600 |
785 |
5,310 |
13,700 |
232 |
|
N700008 |
720566 |
6832676 |
0 |
1 |
2,350 |
125,050 |
75,300 |
822 |
5,230 |
13,900 |
223 |
|
N700010 |
727256 |
6836907 |
0 |
1 |
2,390 |
125,050 |
75,400 |
796 |
4,950 |
14,300 |
222 |
|
N700012 |
734532 |
6837014 |
0 |
1 |
2,740 |
130,150 |
80,400 |
821 |
4,370 |
13,400 |
231 |
|
N700014 |
740408 |
6837916 |
0 |
1 |
2,030 |
121,050 |
71,500 |
802 |
5,330 |
12,900 |
212 |
|
N700016 |
741574 |
6840505 |
0 |
1 |
1,900 |
92,800 |
54,900 |
522 |
3,700 |
8,640 |
162 |
|
N700018 |
750994 |
6847653 |
0 |
1 |
2,340 |
135,400 |
76,600 |
754 |
5,870 |
14,200 |
234 |
|
N700020 |
754948 |
6851513 |
0 |
1 |
2,470 |
111,750 |
67,700 |
949 |
4,240 |
12,100 |
197 |
|
N700022 |
765001 |
6857294 |
0 |
1 |
2,600 |
128,550 |
73,600 |
1,050 |
4,810 |
10,200 |
222 |
|
N700024 |
781493 |
6855076 |
0 |
1 |
2,030 |
101,200 |
58,600 |
1,390 |
3,800 |
8,490 |
172 |
APPENDIX 2C – LAKE MINIGWAL BRINE CHEMISTRY ANALYSIS
|
HOLE ID |
East |
North |
From (m) |
To (m) |
K (mg/L) |
Cl (mg/L) |
Na (mg/L) |
Ca (mg/L) |
Mg (mg/L) |
SO4 (mg/L) |
TDS (g/L) |
|
M700002 |
462878 |
6753653 |
0 |
1 |
1,900 |
154,200 |
96,600 |
706 |
5,900 |
14,300 |
267 |
|
M700004 |
465178 |
6751680 |
0 |
1 |
2,160 |
168,450 |
104,000 |
658 |
5,710 |
12,900 |
288 |
|
M700006 |
516470 |
6735650 |
0 |
1 |
2,270 |
143,150 |
89,300 |
523 |
7,210 |
23,000 |
261 |
|
M700008 |
518949 |
6731636 |
0 |
1 |
1,850 |
138,950 |
87,100 |
594 |
7,580 |
20,500 |
250 |
|
M700010 |
520783 |
6728495 |
0 |
1 |
1,990 |
145,100 |
91,700 |
499 |
8,110 |
24,300 |
267 |
|
M700011 |
477839 |
6749646 |
0 |
1 |
2,470 |
176,750 |
106,000 |
539 |
7,030 |
15,700 |
311 |
|
M700013 |
482455 |
6738102 |
0 |
1 |
2,610 |
165,500 |
103,000 |
310 |
7,290 |
31,800 |
323 |
|
M700015 |
488600 |
6734506 |
0 |
1 |
2,040 |
126,450 |
75,300 |
648 |
6,120 |
19,200 |
237 |
|
M700017 |
507653 |
6736762 |
0 |
1 |
1,750 |
134,000 |
79,600 |
526 |
8,160 |
23,200 |
257 |
|
M700019 |
527552 |
6726613 |
0 |
1 |
1,750 |
149,850 |
84,800 |
549 |
7,890 |
18,300 |
274 |
|
M700023 |
505953 |
6742473 |
0 |
1 |
3,810 |
167,750 |
92,400 |
375 |
11,700 |
26,700 |
316 |
|
M700025 |
509570 |
6745818 |
0 |
1 |
2,850 |
151,400 |
80,300 |
456 |
10,900 |
23,900 |
285 |
|
M700027 |
504869 |
6753891 |
0 |
1 |
3,800 |
133,450 |
78,800 |
500 |
7,990 |
24,900 |
259 |
|
M700029 |
504869 |
6753891 |
0 |
1 |
3,740 |
149,300 |
82,700 |
402 |
12,500 |
32,100 |
292 |
APPENDIX 2D – LAKE BARLEE BRINE CHEMISTRY ANALYSIS
|
HOLE ID |
East |
North |
From (m) |
To (m) |
K (mg/L) |
Cl (mg/L) |
Na (mg/L) |
Ca (mg/L) |
Mg (mg/L) |
SO4 (mg/L) |
TDS (g/L) |
|
E700003 |
766001 |
6706841 |
0 |
1 |
1920 |
146800 |
81100 |
726 |
8180 |
13400 |
250500 |
|
E700005 |
764573 |
6716740 |
0 |
1 |
1680 |
145950 |
81500 |
677 |
8470 |
14200 |
250900 |
|
E700011 |
761574 |
6746205 |
0 |
1 |
1720 |
132450 |
78700 |
1000 |
5680 |
10900 |
228850 |
|
E700013 |
754538 |
6747013 |
0 |
1 |
1150 |
93300 |
54500 |
477 |
3890 |
7200 |
158200 |
|
E700017 |
758045 |
6747653 |
0 |
1 |
1400 |
98400 |
59000 |
978 |
3480 |
7680 |
169350 |
|
E700021 |
737684 |
6727502 |
0 |
1 |
860 |
65750 |
38800 |
554 |
3110 |
6060 |
113950 |
|
E700023 |
742095 |
6731966 |
0 |
1 |
1460 |
129100 |
76900 |
990 |
5400 |
11000 |
223650 |
APPENDIX 2E – LAKE WAY BRINE CHEMISTRY ANALYSIS
“Lake Way” series Chemistry data extracted from AGC Woodward-Clyde Pty Ltd, 1992, Mt Keith Process Water Supply, Lake Way Area, Volume 1, Contained within WMC Resources, Partial Surrender Report for the period 8 December 1992 to 7 December 1995, unpublished report, WAMEX A48586.
|
HOLE ID |
Aquifer |
East |
North |
K (mg/L) |
Cl (mg/L) |
Na (mg/L) |
Ca (mg/L) |
Mg (mg/L) |
SO4 (mg/L) |
TDS (g/L) |
|
Lake Way 2/4 |
Paleochannel |
255050 |
7020250 |
5,200 |
120,000 |
68,000 |
600 |
6,700 |
6,700 |
220 |
|
Lake Way 3/4 |
Paleochannel |
247700 |
7032150 |
6,300 |
130,000 |
83,000 |
520 |
8,200 |
8,200 |
260 |
|
Lake Way 3/5 |
Paleochannel |
247700 |
7032150 |
3,400 |
75,000 |
49,000 |
510 |
5,000 |
5,000 |
160 |
|
Lake Way 3/14 |
Paleochannel |
245050 |
7029800 |
5,300 |
130,000 |
70,000 |
440 |
7,400 |
7,400 |
240 |
|
Lake Way 5/6 |
Paleochannel |
241750 |
7035300 |
6,100 |
130,000 |
77,000 |
570 |
7,000 |
7,000 |
240 |
|
Lake Way 2/4 |
Clay |
255050 |
7020250 |
3,800 |
78,000 |
49,000 |
930 |
3,400 |
3,400 |
150 |
|
Lake Way 2/6 |
Clay |
254250 |
7019550 |
3,400 |
64,000 |
38,000 |
1,100 |
2,500 |
2,500 |
120 |
|
Lake Way 2/7 |
Clay |
253300 |
7018850 |
3,000 |
56,000 |
37,000 |
930 |
2,900 |
2,900 |
120 |
|
Lake Way 3/1 |
Clay |
248420 |
7032900 |
1,500 |
42,000 |
28,000 |
450 |
3,400 |
3,400 |
88 |
|
Lake Way 3/4 |
Clay |
247700 |
7032150 |
2,200 |
49,000 |
31,000 |
750 |
3,900 |
3,900 |
110 |
|
Lake Way 5/7 |
Clay |
242800 |
7034250 |
6,000 |
130,000 |
73,000 |
510 |
7,100 |
7,100 |
240 |
|
Y700002 |
Surficial |
237500 |
7031600 |
8,110 |
149,750 |
86,800 |
359 |
8,930 |
30,600 |
288 |
|
Y700004 |
Surficial |
235968 |
7036128 |
6,950 |
124,750 |
74,200 |
503 |
7,280 |
28,000 |
240 |
|
Y700006 |
Surficial |
237015 |
7039115 |
6,980 |
132,800 |
79,200 |
445 |
8,470 |
31,800 |
258 |
|
Y700008 |
Surficial |
240508 |
7036136 |
6,440 |
142,100 |
78,300 |
407 |
12,000 |
33,000 |
274 |
|
Y700010 |
Surficial |
241352 |
7031891 |
7,210 |
127,200 |
72,800 |
593 |
6,630 |
22,500 |
238 |
|
Y700012 |
Surficial |
241855 |
7026999 |
7,090 |
114,750 |
67,000 |
638 |
5,450 |
21,900 |
216 |
|
Y700020 |
Surficial |
245022 |
7027585 |
6,930 |
123,700 |
73,000 |
624 |
6,440 |
22,100 |
231 |
|
Y700022 |
Surficial |
246105 |
7024796 |
5,160 |
109,300 |
59,700 |
803 |
6,670 |
17,300 |
201 |
APPENDIX 3 – JORC TABLE ONE
Section 1: Sampling Techniques and Data
|
Criteria |
JORC Code explanation |
Commentary |
|
Sampling techniques |
Nature and quality of sampling (eg cut channels, random chips, or specific specialised industry standard measurement tools appropriate to the minerals under investigation, such as down hole gamma sondes, or handheld XRF instruments, etc). These examples should not be taken as limiting the broad meaning of sampling. Include reference to measures taken to ensure sample representivity and the appropriate calibration of any measurement tools or systems used. Aspects of the determination of mineralisation that are Material to the Public Report. In cases where ‘industry standard’ work has been done this would be relatively simple (eg ‘reverse circulation drilling was used to obtain 1 m samples from which 3 kg was pulverised to produce a 30 g charge for fire assay’). In other cases more explanation may be required, such as where there is coarse gold that has inherent sampling problems. Unusual commodities or mineralisation types (eg submarine nodules) may warrant disclosure of detailed information. |
Sampling was undertaken using test pits excavated into the playa surface to a depth of approximately 1m. |
|
Drilling techniques |
Drill type (eg core, reverse circulation, open-hole hammer, rotary air blast, auger, Bangka, sonic, etc) and details (eg core diameter, triple or standard tube, depth of diamond tails, face-sampling bit or other type, whether core is oriented and if so, by what method, etc). |
Not Applicable |
|
Drill sample recovery |
Method of recording and assessing core and chip sample recoveries and results assessed. Measures taken to maximise sample recovery and ensure representative nature of the samples. Whether a relationship exists between sample recovery and grade and whether sample bias may have occurred due to preferential loss/gain of fine/coarse material. |
Brine samples were obtained from all test pits |
|
Logging |
Whether core and chip samples have been geologically and geotechnically logged to a level of detail to support appropriate Mineral Resource estimation, mining studies and metallurgical studies. Whether logging is qualitative or quantitative in nature. Core (or costean, channel, etc) photography. The total length and percentage of the relevant intersections logged. |
All pits were geologically logged by a qualified geologist, noting moisture content of sediments, lithology, colour, induration, grainsize, matrix and structural observations. A digital drill log was developed specifically for this project. |
|
Sub-sampling techniques and sample preparation |
If core, whether cut or sawn and whether quarter, half or all core taken. If non-core, whether riffled, tube sampled, rotary split, etc and whether sampled wet or dry. For all sample types, the nature, quality and appropriateness of the sample preparation technique. Quality control procedures adopted for all sub-sampling stages to maximise representivity of samples. Measures taken to ensure that the sampling is representative of the in situ material collected, including for instance results for field duplicate/second-half sampling. Whether sample sizes are appropriate to the grain size of the material being sampled. |
Geological logs are recorded in the field based on inspection of cuttings. Geological samples are retained for each hole in archive. Sub-sampling was not undertaken. Sample bottles are rinsed with brine which is discarded prior to sampling. All brine samples taken in the field are split into three sub-samples: primary, potential duplicate, and archive. |
|
Quality of assay data and laboratory tests |
The nature, quality and appropriateness of the assaying and laboratory procedures used and whether the technique is considered partial or total. For geophysical tools, spectrometers, handheld XRF instruments, etc, the parameters used in determining the analysis including instrument make and model, reading times, calibrations factors applied and their derivation, etc. Nature of quality control procedures adopted (eg standards, blanks, duplicates, external laboratory checks) and whether acceptable levels of accuracy (ie lack of bias) and precision have been established. |
Primary samples were sent to Bureau Veritas Minerals Laboratory, Perth. Brine samples were analysed using ICP-AES for K, Na, Mg, Ca, with chloride determined by Mohr titration and alkalinity determined volumetrically. Sulphate was calculated from the ICP-AES sulphur analysis
|
|
Verification of sampling and assaying |
The verification of significant intersections by either independent or alternative company personnel. The use of twinned holes. Documentation of primary data, data entry procedures, data verification, data storage (physical and electronic) protocols. Discuss any adjustment to assay data. |
Data entry is done in the field to minimise transposition errors. Brine assay results are received from the laboratory in digital format to prevent transposition errors and these data sets are subject to the quality control described above. Independent verification of significant intercepts was not considered warranted given the relatively consistent nature of the brine. |
|
Location of data points |
Accuracy and quality of surveys used to locate drill holes (collar and down-hole surveys), trenches, mine workings and other locations used in Mineral Resource estimation. Specification of the grid system used. Quality and adequacy of topographic control. |
Hole co-ordinates were captured using hand held GPS. Coordinates were provided in GDA 94_MGA Zone 51. Topographic control is obtained using Geoscience Australia’s 3-second digital elevation product. Topographic control is not considered critical as the salt lakes are generally flat lying and the water table is taken to be the top surface of mineralisation. |
|
Data spacing and distribution |
Data spacing for reporting of Exploration Results. Whether the data spacing and distribution is sufficient to establish the degree of geological and grade continuity appropriate for the Mineral Resource and Ore Reserve estimation procedure(s) and classifications applied. Whether sample compositing has been applied. |
Data spacing is variable and is not on an exact grid due to the irregular nature of the salt lake shape and difficulty obtaining access to some part of the salt lake.
|
|
Orientation of data in relation to geological structure |
Whether the orientation of sampling achieves unbiased sampling of possible structures and the extent to which this is known, considering the deposit type. If the relationship between the drilling orientation and the orientation of key mineralised structures is considered to have introduced a sampling bias, this should be assessed and reported if material. |
Not Applicable |
|
Sample security |
The measures taken to ensure sample security. |
All brine samples were marked and kept onsite before transport to the laboratory. All remaining sample and duplicates are stored in the Perth office in climate-controlled conditions. Chain of Custody system is maintained. |
|
Audits or reviews |
The results of any audits or reviews of sampling techniques and data. |
Data review is summarised in Quality of assay data and laboratory tests and Verification of sampling and assaying. No audits were undertaken. |
Section 2: Reporting of Exploration Results
|
Criteria |
JORC Code explanation |
Commentary |
|
Mineral tenement and land tenure status |
Type, reference name/number, location and ownership including agreements or material issues with third parties such as joint ventures, partnerships, overriding royalties, native title interests, historical sites, wilderness or national park and environmental settings. The security of the tenure held at the time of reporting along with any known impediments to obtaining a licence to operate in the area.
|
Details are presented in the report.
|
|
Exploration done by other parties |
Acknowledgment and appraisal of exploration by other parties. |
Details are presented in the report.
|
|
Geology |
Deposit type, geological setting and style of mineralisation. |
Salt Lake Brine Deposit
|
|
Drill hole Information |
A summary of all information material to the understanding of the exploration results including a tabulation of the following information for all Material drill holes: o easting and northing of the drill hole collar o elevation or RL (Reduced Level – elevation above sea level in metres) of the drill hole collar o dip and azimuth of the hole o down hole length and interception depth o hole length. If the exclusion of this information is justified on the basis that the information is not Material and this exclusion does not detract from the understanding of the report, the Competent Person should clearly explain why this is the case. |
Details are presented in the report.
|
|
Data aggregation methods |
In reporting Exploration Results, weighting averaging techniques, maximum and/or minimum grade truncations (eg cutting of high grades) and cut-off grades are usually Material and should be stated. Where aggregate intercepts incorporate short lengths of high grade results and longer lengths of low grade results, the procedure used for such aggregation should be stated and some typical examples of such aggregations should be shown in detail. The assumptions used for any reporting of metal equivalent values should be clearly stated. |
Details are presented in the report.
|
|
Relationship between mineralisation widths and intercept lengths |
These relationships are particularly important in the reporting of Exploration Results. If the geometry of the mineralisation with respect to the drill hole angle is known, its nature should be reported. If it is not known and only the down hole lengths are reported, there should be a clear statement to this effect (eg ‘down hole length, true width not known’). |
The brine resource is inferred to be consistent and continuous through the full thickness of the sediments. |
|
Diagrams |
Appropriate maps and sections (with scales) and tabulations of intercepts should be included for any significant discovery being reported These should include, but not be limited to a plan view of drill hole collar locations and appropriate sectional views. |
Addressed in the announcement. |
|
Balanced reporting |
Where comprehensive reporting of all Exploration Results is not practicable, representative reporting of both low and high grades and/or widths should be practiced to avoid misleading reporting of Exploration Results. |
All results have been included. |
|
Other substantive exploration data |
Other exploration data, if meaningful and material, should be reported including (but not limited to): geological observations; geophysical survey results; geochemical survey results; bulk samples – size and method of treatment; metallurgical test results; bulk density, groundwater, geotechnical and rock characteristics; potential deleterious or contaminating substances. |
All material exploration data reported. |
|
Further work |
The nature and scale of planned further work (eg tests for lateral extensions or depth extensions or large-scale step-out drilling). Diagrams clearly highlighting the areas of possible extensions, including the main geological interpretations and future drilling areas, provided this information is not commercially sensitive. |
Aircore / RC drilling to defined paleovalley structure and provide brine samples with depth. Hydraulic testing be undertaken, for instance pumping tests from bores and/or trenches to determine, aquifer properties, expected production rates and infrastructure design (trench and bore size and spacing). Diamond Core drilling to obtain sample for porosity determination. Lake recharge dynamics be studied to determine the lake water balance and subsequent production water balance. For instance, simultaneous data recording of rainfall and subsurface brine level fluctuations to understand the relationship between rainfall and lake recharge, and hence the brine recharge dynamics of the lake. |
For further information please visit www.saltlakepotash.com.au or contact:
|
Matt Syme/Sam Cordin |
Salt Lake Potash Limited |
Tel: +61 8 9322 6322 |
|
Jo Battershill |
Salt Lake Potash Limited |
Tel: +44 (0) 20 7478 3900 |
|
Colin Aaronson/Richard Tonthat |
Grant Thornton UK LLP (Nominated Adviser) |
Tel: +44 (0) 20 7383 5100 |
|
Derrick Lee/Beth McKiernan |
Cenkos Securities plc (Joint Broker) |
Tel: +44 (0) 131 220 6939 |
|
Jerry Keen/Toby Gibbs
|
Shore Capital (Joint broker) |
Tel: +44 (0) 20 7468 7967
|
[1] Bell et al, 2012, WASANT Paleovalley Map – Distribution of Palaeovalley in Arid and Semi-arid WA-SA-NT. Geoscience Australia Thematic Map.
[2] Johnson, S.L., Commander, D.P., and O’Boy, C.A. 1999, Groundwater resources of the Northern Goldfields, Western Australia: Water and Rivers Commission, Hydrogeological Record Series, Report HG 2, 57p.
[3] DeBroekert and Sandiford (2005), Buried Inset-Valleys in the Eastern Yilgarn Craton, Western Australia: Geomorphology, Age, and Allogenic Control. The Journal of Geology, 2005, volume 113, p. 471-493
[4] http://www.ga.gov.au/scientific-topics/hazards/flood/wofs
[5] Johnson, (2007) Groundwater abstraction and aquifer response in the Roe Palaeodrainage (1990-2001). Department of Water Hydrogeological Record Series Report HG23 October 2007
[6] Bowler, J.M., 1986. Spatial variability and hydrologic evolution of Australian lake basins: analogues for Pleistocene hydrologic change and evaporite formation. Palaeogeography, Palaeoclimatology, Palaeoecology, 54, 21-41.
Salt Lake Potash #SO4 – Interim results
Salt Lake Potash #SO4 – Interim results
OPERATING AND FINANCIAL REVIEW
The Company’s aim is to develop the first salt-lake brine Sulphate of Potash (SOP) operation in Australia, starting with a Demonstration Plant producing up to 50,000tpa of SOP, at the Goldfields Salt Lakes Project (GSLP) located in the Northern Goldfields of Western Australia. The Company’s multi-lake portfolio, and the comprehensive technical achievements to date, highlight the potential for a very economic, large scale and long term project.
LAKE WAY
Ø Subsequent to the end of the period, the Company entered a Memorandum of Understanding (MOU) with Blackham Resources Limited (Blackham) to investigate the potential development of an SOP operation based at Lake Way, near Wiluna. Under the MOU, the Company will acquire Blackham’s brine rights and Blackham will acquire gold rights to the Company’s Lake Way holdings, with each company retaining a royalty on their respective holdings.
The Company will investigate the development of an SOP operation at Lake Way, including initially a 40-50,000tpa Demonstration Plant.
LAKE WELLS
Evaporation Pond Testwork
Ø The Company successfully completed field trials testing its on-lake, unlined evaporation pond model, which will result in significant capital cost advantages for the GSLP.
Ø Comprehensive geological and geotechnical investigation confirms the widespread availability of ideal in-situ clay materials ideal for use in evaporation pond construction. Modelling based on geotechnical properties of the clays confirms the potential to build unlined, on-lake ponds with negligible seepage inefficiency.
Ø Amec Foster Wheeler estimate that comparative costs for 400ha of on-lake ponds are $1.6m (unlined) and $42.2m (HDPE lined), highlighting a significant capex advantage for the Project.
Process Testwork
Ø The Company completed a comprehensive testwork program at globally recognised potash process consultants, Saskatchewan Research Council (SRC) that validated and refined the parameters used in the process plant flowsheet for the GSLP. Importantly, the testwork was conducted on a 60kg representative sample of kainite harvest salt produced on site at Lake Wells.
Ø SRC will conduct further optimisation tests followed by a continuous locked cycle operation, to produce significant quantities of flotation product and SOP for further testing and marketing.
Ø The Site Evaporation Trial (SET) at Lake Wells has now processed approximately 357 tonnes of brine and produced over 8 tonnes of harvest salts.
Surface Aquifer Characterisation and Deep Aquifer Exploration
Ø The Company continued sustained pump tests on test trenches across Lake Wells, providing reliable data for the surface aquifer hydrogeological model for Lake Wells.
Ø The Company mobilised an on-lake drill rig to test deep aquifer characteristics and identify potential high yield portions of the basal aquifer.
LAKE BALLARD
Ø An initial surface aquifer exploration program was completed at Lake Ballard, comprising a total of 160 shallow test pits and 10 test trenches. This work provides preliminary data for the geological and hydrological models for the surface aquifer of the Lake, as well as brine, geological and geotechnical samples.
LAKE IRWIN
Ø An initial surface aquifer exploration program was completed at Lake Irwin, comprising a total of 27 shallow test pits and 2 test trenches. This work provides preliminary data for the geological and hydrological models of the surface aquifer of the Lake, as well as brine, geological and geotechnical samples.
REGIONAL LAKES
Ø The Company undertook initial surface brine sampling of the near surface aquifer and reconnaissance of access and infrastructure at all remaining Lakes held under the GSLP.
Results of Operations
Net loss after tax for the half year ended 31 December 2017 was $5,354,804 (31 December 2016: $4,969,027).
(i) Exploration and evaluation expenses were $4,549,568 (31 December 2016: $4,282,810), which is attributable to the Group’s accounting policy of expensing exploration and evaluation expenditure incurred by the Group subsequent to the acquisition of the rights to explore and up to the final investment decision to commence construction for each separate area of interest; and
(ii) Business development expenses increased to $374,784 (31 December 2016: $186,990) which is attributable to additional business development and investor relations activities required to support the growth and development of the Goldfields Salt Lakes Project.
Financial Position
At 31 December 2017, the Company had cash reserves of $10.5 million (30 June 2017: $15.6 million) and net assets of $12.3 million (30 June 2017: $17.0 million). The Company is in a financial position to conduct its current and planned exploration and development activities.
SIGNIFICANT POST BALANCE DATE EVENTS
Other than as disclosed below, at the date of this report there were no significant events occurring after balance date requiring disclosure.
(i) On 12 March 2018, the Company entered a Memorandum of Understanding (MOU) with Blackham Resources Limited (Blackham) to investigate the potential development of a Sulphate of Potash (SOP) operation based at Lake Way, near Wiluna. Under the MOU, the Company will acquire Blackham’s brine rights and Blackham will acquire gold rights to the Company’s Lake Way holdings, with each company retaining a royalty on their respective holdings.
AUDITOR’S INDEPENDENCE DECLARATION
Section 307C of the Corporations Act 2001 requires our auditors, Ernst & Young, to provide the directors of Salt Lake Potash Limited with an Independence Declaration in relation to the review of the half year financial report. This Independence Declaration is attached to and forms part of this Directors’ Report.
Signed in accordance with a resolution of the Directors.
MATTHEW SYME
CEO
16 March 2018
DIRECTORS’ DECLARATION
In the opinion of the Directors of Salt Lake Potash Limited:
1. the interim consolidated financial statements comprising the statement of profit or loss and other comprehensive income, statement of financial position, statement of cash flows, statement of changes in equity and notes set out on pages 9 to 13 are in accordance with the Corporations Act 2001 including:
1. giving a true and fair view of the financial position of the consolidated entity as at 31 December 2017 and of its performance and cash flows for the six months ended on that date; and
2. complying with Australian Accounting Standard AASB 134 Interim Financial Reporting and Corporations Regulations 2001; and
2. there are reasonable grounds to believe that the Company will be able to pay its debts as and when they become due and payable.
Signed in accordance with a resolution of Directors:
MATTHEW SYME
CEO
16 March 2018
CONSOLIDATED STATEMENT OF PROFIT OR LOSS AND OTHER COMPREHENSIVE INCOME FOR THE HALF YEAR ENDED 31 DECEMBER 2017
|
31 December 2017 |
31 December 2016 |
||
|
Notes |
$ |
$ |
|
|
Finance income |
145,705 |
71,955 |
|
|
Research and development rebate |
456,709 |
– |
|
|
Exploration and evaluation expenses |
(4,549,568) |
(4,282,810) |
|
|
Corporate and administrative expenses |
(448,894) |
(382,760) |
|
|
Business development expenses |
(374,784) |
(186,990) |
|
|
Share based payments expenses |
(583,972) |
(188,422) |
|
|
Loss before tax |
(5,354,804) |
(4,969,027) |
|
|
Income tax expense |
– |
– |
|
|
Loss for the period |
(5,354,804) |
(4,969,027) |
|
|
Other comprehensive income Items that may be reclassified subsequently to profit or loss: |
|||
|
Exchange differences arising during the period |
– |
(120) |
|
|
Other comprehensive (loss)/ income for the period, net of tax |
– |
(120) |
|
|
Total comprehensive loss for the period |
(5,354,804) |
(4,969,147) |
|
|
Basic and diluted loss per share attributable to the ordinary equity holders of the company (cents per share) |
(3.10) |
(3.71) |
The above Consolidated Statement of Profit or Loss and other Comprehensive Income should be read in conjunction with the accompanying notes.
CONSOLIDATED STATEMENT OF FINANCIAL POSITION AS AT 31 DECEMBER 2017
|
Notes |
31 December |
30 June |
|
|
ASSETS |
|||
|
Current Assets |
|||
|
Cash and cash equivalents |
10,499,568 |
15,596,759 |
|
|
Trade and other receivables |
221,131 |
300,058 |
|
|
Total Current Assets |
10,720,699 |
15,896,817 |
|
|
Non-Current Assets |
|||
|
Property, plant and equipment |
353,852 |
303,511 |
|
|
Exploration and evaluation expenditure |
3 |
2,276,736 |
2,276,736 |
|
Total Non-Current Assets |
2,630,588 |
2,580,247 |
|
|
TOTAL ASSETS |
13,351,287 |
18,477,064 |
|
|
LIABILITIES |
|||
|
Current Liabilities |
|||
|
Trade and other payables |
973,969 |
1,348,791 |
|
|
Finance lease |
13,011 |
13,011 |
|
|
Provisions |
28,379 |
19,181 |
|
|
Total Current Liabilities |
1,015,359 |
1,380,983 |
|
|
Non-Current Liabilities |
|||
|
Finance lease |
43,724 |
49,638 |
|
|
Total Non-Current Liabilities |
43,724 |
49,638 |
|
|
TOTAL LIABILITIES |
1,059,083 |
1,430,621 |
|
|
NET ASSETS |
12,292,204 |
17,046,443 |
|
|
EQUITY |
|||
|
Contributed equity |
4 |
123,501,153 |
123,484,561 |
|
Reserves |
5 |
1,405,797 |
821,824 |
|
Accumulated losses |
(112,614,746) |
(107,259,942) |
|
|
TOTAL EQUITY |
12,292,204 |
17,046,443 |
|
The above Consolidated Statement of Financial Position should be read in conjunction with the accompanying notes.
CONSOLIDATED STATEMENT OF CHANGES IN EQUITY FOR THE HALF YEAR ENDED 31 DECEMBER 2017
|
CONSOLIDATED |
Contributed Equity |
Share- Based Payment Reserve |
Foreign Currency Translation Reserve |
Accumulated Losses |
Total |
|
|
Balance at 1 July 2017 |
123,484,561 |
821,824 |
– |
(107,259,942) |
17,046,443 |
|
|
Net loss for the period |
– |
– |
– |
(5,354,804) |
(5,354,804) |
|
|
Total comprehensive loss for the period |
(5,354,804) |
(5,354,804) |
||||
|
Transactions with owners, recorded directly in equity |
||||||
|
Shares issued in lieu of fees |
18,476 |
– |
– |
– |
18,476 |
|
|
Share based payment expense |
– |
583,972 |
– |
– |
583,972 |
|
|
Share issue costs |
(1,884) |
– |
– |
– |
(1,884) |
|
|
Balance at 31 December 2017 |
123,501,153 |
1,405,797 |
– |
(112,614,746) |
12,292,204 |
|
|
Balance at 1 July 2016 |
106,761,669 |
240,848 |
454,468 |
(98,059,433) |
9,397,552 |
|
|
Net loss for the period |
– |
– |
– |
(4,969,027) |
(4,969,027) |
|
|
Exchange differences on translation of foreign operations |
– |
– |
(120) |
– |
(120) |
|
|
Total comprehensive loss for the period |
– |
– |
(120) |
(4,969,027) |
(4,969,147) |
|
|
Transactions with owners, recorded directly in equity |
||||||
|
Shares issued in lieu of fees |
86,400 |
– |
– |
– |
86,400 |
|
|
Share based payment expense |
– |
188,422 |
– |
– |
188,422 |
|
|
Share issue costs |
(1,794) |
– |
– |
– |
(1,794) |
|
|
Balance at 31 December 2016 |
106,846,275 |
429,270 |
454,348 |
(103,028,460) |
4,701,433 |
|
CONSOLIDATED STATEMENT OF CASH FLOWS FOR THE HALF YEAR ENDED 31 DECEMBER 2017
|
31 December 2017 |
31 December 2016 |
|
|
Cash flows from operating activities |
||
|
Payments to suppliers and employees |
(5,594,353) |
(4,028,053) |
|
Research and development rebate received |
456,709 |
– |
|
Exploration investment scheme received |
30,000 |
– |
|
Interest received |
133,705 |
70,930 |
|
Net cash outflow from operating activities |
(4,973,939) |
(3,957,123) |
|
Cash flows from investing activities |
||
|
Payments for property, plant and equipment |
(83,030) |
(71,664) |
|
Net cash outflow from investing activities |
(83,030) |
(71,664) |
|
Cash flows from financing activities |
||
|
Transaction costs from the issue of shares |
(40,222) |
– |
|
Net cash inflow from financing activities |
(40,222) |
– |
|
Net decrease in cash and cash equivalents held |
(5,097,191) |
(4,028,787) |
|
Net foreign exchange differences |
– |
15 |
|
Cash and cash equivalents at the beginning of the half year |
15,596,759 |
7,498,285 |
|
Cash and cash equivalents at the end of the half year |
10,499,568 |
3,469,513 |
The above Consolidated Statement of Cash Flows should be read in conjunction with the accompanying notes.
NOTES TO THE FINANCIAL STATEMENTS FOR THE HALF YEAR ENDED 31 DECEMBER 2017
1. SUMMARY OF SIGNIFICANT ACCOUNTING POLICIES
(a) Statement of Compliance
The interim condensed consolidated financial statements of the Group for the half year ended 31 December 2017 were authorised for issue in accordance with the resolution of the directors on 9 March 2018.
The interim condensed consolidated financial statements for the half year reporting period ended 31 December 2017 have been prepared in accordance with Accounting Standard AASB 134 Interim Financial Reporting and the Corporations Act 2001.
This half year financial report does not include all the notes of the type normally included in an annual financial report. Accordingly, this report is to be read in conjunction with the annual report of Salt Lake Potash Limited for the year ended 30 June 2017 and any public announcements made by Salt Lake Potash Limited and its controlled entities during the half year reporting period in accordance with the continuous disclosure requirements of the Corporations Act 2001.
(b) Basis of Preparation of Half Year Financial Report
The financial statements have been prepared on an accruals basis and are based on historical cost. All amounts are presented in Australian dollars.
The financial statements for the half-year have been prepared on the basis of going concern, which contemplates continuity of normal business activities and the realisation of assets and settlement of liabilities in the ordinary course of business. Certain comparatives have been reclassified to conform with current year presentation.
(c) New Accounting Standards
In the current period, the Group has adopted all of the new and revised standards, interpretations and amendments that are relevant to its operations and effective for annual reporting periods beginning on or after 1 July 2017.
The adoption of new and revised standards and amendments has not affected the amounts reported for the current or prior half-year periods.
The Group has not early adopted any other standard, interpretation or amendment that has been issued but is not yet effective.
2. SEGMENT INFORMATION
AASB 8 requires operating segments to be identified on the basis of internal reports about components of the Consolidated Entity that are regularly reviewed by the chief operating decision maker in order to allocate resources to the segment and to assess its performance.
The Consolidated Entity operates in one segment, being mineral exploration. This is the basis on which internal reports are provided to the Directors for assessing performance and determining the allocation of resources within the Consolidated Entity.
3. EXPLORATION AND EVALUATION
|
(a) Areas of Interest |
|||
|
SOP Project |
2,276,736 |
2,276,736 |
|
|
Carrying amount at end of period 1 |
2,276,736 |
2,276,736 |
|
|
(b) Reconciliation |
|||
|
Carrying amount at start of period |
2,276,736 |
2,276,736 |
|
|
Impairment losses |
– |
– |
|
|
Carrying amount at end of period 1 |
2,276,736 |
2,276,736 |
Notes:
1 The ultimate recoupment of costs carried forward for exploration and evaluation is dependent on the successful development and commercial exploitation or sale of the respective areas of interest.
SOP Project
Salt Lake holds a number of large salt lake brine projects (Projects) in Western Australia, South Australia and the Northern Territory, each having potential to produce highly sought after Sulphate of Potash (SOP) for domestic and international fertiliser markets.
4. CONTRIBUTED EQUITY
|
31 December 2017 |
30 June 2017 |
|
|
Share Capital |
||
|
175,049,596 (30 June 2017:175,007,596) Ordinary Shares |
123,501,153 |
123,484,561 |
|
123,501,153 |
123,484,561 |
Movement in Share Capital during the past six months
|
Number of Ordinary Shares |
Issue Price $ |
$ |
||
|
01-Jul-17 |
Opening Balance |
175,007,596 |
– |
123,484,561 |
|
19-Aug-17 |
Share issue 1 |
42,000 |
0.48 |
18,476 |
|
Jul-16 to Jun-17 |
Share issue costs |
– |
– |
(1,884) |
|
31-Dec-17 |
Closing balance |
175,049,596 |
– |
123,501,153 |
Notes:
1. Issued to an advisor of the Company in lieu of fees.
5. RESERVES
|
Notes |
31 December 2017 |
30 June 2017 |
|
|
Share-based payment reserve |
5(a) |
1,405,797 |
821,824 |
|
1,405,797 |
821,824 |
Movement in share-based payment reserve during the past six months
|
Date |
Details |
Number of Performance Rights |
Number of Options |
$ |
|
1 Jul 2017 |
Opening Balance |
3,100,000 |
2,500,000 |
821,824 |
|
22 Nov 2017 |
Issue of Incentive Options |
– |
1,100,000 |
– |
|
15 Dec 2017 |
Issue of Incentive Options |
– |
800,000 |
– |
|
15 Dec 2017 |
Issue of Performance Rights |
2,300,000 |
– |
– |
|
1 Jul – 31 Dec 2017 |
Share Based Payments Expenses |
– |
– |
583,972 |
|
31 Dec 2017 |
Closing Balance |
5,400,000 |
4,400,000 |
1,405,797 |
6. SHARE-BASED PAYMENTS
For the six months end 31 December 2017, the Group has recognised $583,972 of share-based payments expenses in the statement of profit or loss (31 December 2016: $188,422).
(a) Options
The fair value of the equity-settled incentive options granted is estimated as at the date of grant using the Binomial option valuation model taking into account the terms and conditions upon which the options were granted.
|
Inputs |
Series 1 |
Series 2 |
Series 3 |
|
Exercise price |
$0.40 |
$0.50 |
$0.60 |
|
Grant date share price |
$0.500 |
$0.500 |
$0.500 |
|
Dividend yield 1 |
– |
– |
– |
|
Volatility 2 |
70% |
70% |
70% |
|
Risk-free interest rate |
1.99% |
1.99% |
1.99% |
|
Grant date |
22-Nov-17 |
22-Nov-17 |
22-Nov-17 |
|
Expiry date |
30-Jun-21 |
30-Jun-21 |
30-Jun-21 |
|
Expected life of option 3 |
3.61 |
3.61 |
3.61 |
|
Fair value at grant date |
$0.228 |
$0.207 |
$0.188 |
Notes:
1 The dividend yield reflects the assumption that the current dividend payout will remain unchanged.
2 The expected volatility reflects the assumption that the historical volatility is indicative of future trends, which may not necessarily be the actual outcome.
3 The expected life of the options is based on the expiry date of the options as there is limited track record of the early exercise of options
|
Inputs |
Series 4 |
Series 5 |
Series 6 |
|
Exercise price |
$0.50 |
$0.60 |
$0.70 |
|
Grant date share price |
$0.465 |
$0.465 |
$0.465 |
|
Dividend yield 1 |
– |
– |
– |
|
Volatility 2 |
70% |
70% |
70% |
|
Risk-free interest rate |
2.13% |
2.13% |
2.13% |
|
Grant date |
15-Dec-17 |
15-Dec-17 |
15-Dec-17 |
|
Expiry date |
30-Jun-21 |
30-Jun-21 |
30-Jun-21 |
|
Expected life of option 3 |
3.54 |
3.54 |
3.54 |
|
Fair value at grant date |
$0.317 |
$0.301 |
$0.288 |
Notes:
1 The dividend yield reflects the assumption that the current dividend payout will remain unchanged.
2 The expected volatility reflects the assumption that the historical volatility is indicative of future trends, which may not necessarily be the actual outcome.
3 The expected life of the options is based on the expiry date of the options as there is limited track record of the early exercise of options.
(b) Performance rights
The fair value of performance rights granted is estimated as at the date of grant based on the underlying share price (being the five day volume weighted average share price prior to granting). The table below lists the inputs to the valuation model used for the performance rights granted by the Group:
|
Inputs |
Series 1 |
Series 2 |
Series 3 |
Series 4 |
|
Milestones |
Pre-Feasibility Study |
Definitive Feasibility Study |
Construction |
Production |
|
Exercise price |
– |
– |
– |
– |
|
Grant date share price |
$0.465 |
$0.465 |
$0.465 |
$0.465 |
|
Grant date |
15-Dec-17 |
15-Dec-17 |
15-Dec-17 |
15-Dec-17 |
|
Expiry date |
30-Jun-18 |
30-Jun-19 |
30-Jun-20 |
30-Jun-21 |
|
Expected life |
0.5 years |
1.5 years |
2.5 years |
3.5 years |
|
Fair value at grant date |
$0.486 |
$0.486 |
$0.486 |
$0.486 |
7. COMMITMENTS AND CONTINGENCIES
Management have identified the following material commitments for the consolidated group as at 31 December 2017 and 30 June 2017:
|
31 December 2017 |
30 June 2017 |
|
|
$ |
$ |
|
|
Finance lease commitments |
||
|
Within one year |
13,011 |
13,011 |
|
Later than one year but not later than five years |
43,724 |
49,638 |
|
56,735 |
62,649 |
|
|
Operating lease commitments |
||
|
Within one year |
67,122 |
– |
|
Later than one year but not later than five years |
134,244 |
– |
|
201,366 |
– |
|
|
Exploration commitments |
||
|
Within one year |
652,000 |
1,061,000 |
|
Later than one year but not later than five years |
– |
– |
|
652,000 |
1,061,000 |
8. DIVIDENDS PAID OR PROVIDED FOR
No dividend has been paid or provided for during the half year (31 December 2016: nil).
9. FINANCIAL INSTRUMENTS
Fair Value Measurement
At 31 December 2017, the Group had no material financial assets and liabilities that are measured at fair value on a recurring basis and at 31 December 2017, the carrying amount of financial assets and financial liabilities for the Group is considered to approximate their fair values.
10. SUBSEQUENT EVENTS AFTER BALANCE DATE
Other than as disclosed below, at the date of this report there were no significant events occurring after balance date requiring disclosure.
(i) On 12 March 2018, the Company entered a Memorandum of Understanding (MOU) with Blackham Resources Limited (Blackham) to investigate the potential development of a Sulphate of Potash (SOP) operation based at Lake Way, near Wiluna. Under the MOU, the Company will acquire Blackham’s brine rights and Blackham will acquire gold rights to the Company’s Lake Way holdings, with each company retaining a royalty on their respective holdings.
For further information please visit www.saltlakepotash.com.au or contact:
|
Matt Syme/Sam Cordin |
Salt Lake Potash Limited |
Tel: +61 8 9322 6322 |
|
Jo Battershill |
Salt Lake Potash Limited |
Tel: +44 (0) 20 7478 3900 |
|
Colin Aaronson/Richard Tonthat |
Grant Thornton UK LLP (Nominated Adviser) |
Tel: +44 (0) 20 7383 5100 |
|
Derrick Lee/Beth McKiernan |
Cenkos Securities plc (Joint Broker) |
Tel: +44 (0) 131 220 6939 |
|
Jerry Keen/Toby Gibbs
|
Shore Capital (Joint broker) |
Tel: +44 (0) 20 7468 7967 |
Salt Lake Potash #SO4 – New Company Presentation
The Company is pleased to advise that a new corporate presentation is now available to view on the Company’s website: www.saltlakepotash.com.au
For further information please visit www.saltlakepotash.com.au or contact:
|
Matt Syme/Sam Cordin |
Salt Lake Potash Limited |
Tel: +61 8 9322 6322 |
|
Jo Battershill |
Salt Lake Potash Limited |
Tel: +44 (0) 20 7478 3900 |
|
Colin Aaronson/Richard Tonthat |
Grant Thornton UK LLP (Nominated Adviser) |
Tel: +44 (0) 20 7383 5100 |
|
Derrick Lee/Beth McKiernan |
Cenkos Securities plc (Joint Broker) |
Tel: +44 (0) 131 220 6939 |
|
Jerry Keen/Toby Gibbs
|
Shore Capital (Joint broker) |
Tel: +44 (0) 20 7468 7967 |
Salt Lake Potash #SO4 – MOU With Blackham Resources For Potential Development Of Lake Way
Salt Lake Potash (SLP) is pleased to announce that the Company has entered a Memorandum of Understanding (MOU) with Blackham Resources Limited (Blackham) to investigate the potential development of a Sulphate of Potash (SOP) operation based at Lake Way, near Wiluna.
SLP holds approximately 290km2 of tenure over the Lake Way Paleochannel, as part of the Goldfields Salt Lakes Project (GSLP). Blackham is the owner of the Matilda-Wiluna Gold Operation and holds approximately 64km2 at the Northern End of the Lake. This surrounds the former Williamson Pit, last mined in 2006 and now filled with brine at an exceptional grade of 25kg/m3 of SOP.
Under the MOU, SLP will acquire Blackham’s brine rights and Blackham will acquire gold rights to SLP’s Lake Way holdings, with each company retaining a royalty on their respective holdings. The parties will also co-operate to exchange data and facilitate activities on each other properties.
SLP will investigate the development of an SOP operation at Lake Way, including initially a 40-50,000tpa Demonstration Plant. SLP will sole fund the evaluation and development of any SOP operation at Lake Way. Lake Way has some compelling advantages which make it potentially an ideal site for an SOP operation, including:
- Substantial capital and operating savings from sharing overheads and infrastructure with the Wiluna Gold Mine, benefits which both Companies would capture. This includes potentially the accommodation camp, flights, power, maintenance, infrastructure and other costs.
- The site has an excellent freight solution, located 2km from Goldfields Highway, which is permitted for heavy haulage 4 trailer road trains to the railhead at Leonora. It is also adjacent to the Goldfields Gas Pipeline.
- A Demonstration Plant would likely be built on Blackham’s existing Mining Licences, already subject of a Native Title Agreement.
- SLP would dewater the existing Williamson Pit, prior to Blackham mining, planned for early 2019. The pit contains an estimated 1.2GL of brine at the exceptional grade of 25kg/m3 of SOP (Refer Appendix 1 for Williamson Pit brine samples details). This brine is potentially the ideal starter feed for evaporation ponds, having already evaporated from the normal Lake Way brine grade, which averages around 14kg/m3.
- The high grade brines at Lake Way will result in lower capital and operating costs due to lower extraction and evaporation requirements.
- There would be substantial savings to both parties from co-operating on activities on each other’s ground.
- Historical exploration and initial sampling indicate the presence of clays in the upper levels of the lake which should be amenable to low cost, on-lake evaporation pond construction.
SLP will complete a Scoping Study for a potential SOP operation at Lake Way, including a Demonstration Plant, by mid-2018, in time to allow a decision on dewatering the Williamson Pit. There is substantial historical data available for Lake Way and the companies have already undertaken preliminary sampling in the Blackham area. Along with the extensive, high quality technical work undertaken at SLP’s other lakes, which has substantial application at Lake Way, a Scoping Study can be reliably undertaken in a much shorter timeframe than would normally be the case.
SLP CEO Matt Syme said “We are pleased to reach this agreement with Blackham which could potentially bring very substantial benefit to both companies, and adds significant value from mineral rights to which neither company ascribed value as a standalone. Lake Way appears to be an ideal site for our SOP Demonstration Plant and subsequent expansions. We expect it would result in material time and cost savings for us and also bring significant benefits to the Wiluna Community. It appears to have the best combination in Australia of scale, brine chemistry, permitting and infrastructure access and justifies the effort to prove its potential. Work will continue in parallel at Lake Wells, where our Mining Lease Application is in progress.”
LAKE WAY
Lake Way is located in the Goldfields region of Western Australia, less than 15km south of Wiluna. The surface area of the Lake is over 200km2.
Lake Way was identified due to its strategic location and significant infrastructure advantages. The Wiluna region is an historic mining precinct dating back to the late 19th century. It has been a prolific nickel and gold mining region and therefore has well developed, high quality infrastructure in place.
The Goldfields Highway is a high quality sealed road permitted to carry quad road trains and passes 2km from the Lake. The Goldfields Gas Pipeline is adjacent to SLP’s tenements, running past the eastern side of the Lake.
As described in SLP’s ASX Announcement dated 12 December 2017, Lake Way has been extensively explored and mined previously. A paleochannel has been well defined along the Eastern edge of the lake, including brine sampling at depth and test pumping of the basal aquifer.
Competent Persons Statement
The information in this report that relates to Exploration Results for Lake Way is based on information compiled by Mr Ben Jeuken, who is a member Australian Institute of Mining and Metallurgy. Mr Jeuken is employed by Groundwater Science Pty Ltd, an independent consulting company. Mr Jeuken has sufficient experience, which is relevant to the style of mineralisation and type of deposit under consideration and to the activity, which he is undertaking to qualify as a Competent Person as defined in the 2012 Edition of the ‘Australasian Code for Reporting of Exploration Results, Mineral Resources and Ore Reserves’. Mr Jeuken consents to the inclusion in the report of the matters based on his information in the form and context in which it appears.
Forward Looking Statements
This announcement may include forward-looking statements. These forward-looking statements are based on Salt Lake’s expectations and beliefs concerning future events. Forward looking statements are necessarily subject to risks, uncertainties and other factors, many of which are outside the control of Salt Lake, which could cause actual results to differ materially from such statements. Salt Lake makes no undertaking to subsequently update or revise the forward-looking statements made in this announcement, to reflect the circumstances or events after the date of that announcement.
APPENDIX 1 – BRINE CHEMISTRY ANALYSIS
|
PIT SAMPLE |
East |
North |
Depth (m) |
K (mg/L) |
Cl (mg/L) |
Na (mg/L) |
Ca (mg/L) |
Mg (mg/L) |
SO4 (mg/L) |
TDS (g/L) |
|
Y800006 |
233338 |
7035669 |
1 |
11,400 |
180,250 |
106,000 |
173 |
14,400 |
47,700 |
371 |
|
Y800008 |
233338 |
7035669 |
20 |
11,400 |
181,300 |
106,000 |
175 |
14,400 |
48,000 |
371 |
|
Y800010 |
233338 |
7035669 |
35 |
11,300 |
180,800 |
107,000 |
174 |
14,700 |
48,300 |
373 |
|
Y800012 |
233334 |
7035874 |
1 |
11,100 |
179,050 |
106,000 |
171 |
14,200 |
47,100 |
368 |
|
Y800014 |
233334 |
7035874 |
20 |
11,400 |
171,150 |
107,000 |
180 |
14,400 |
47,100 |
378 |
|
Y800016 |
233334 |
7035874 |
35 |
11,500 |
182,000 |
111,000 |
179 |
14,700 |
49,200 |
373 |
|
Y800018 |
233335 |
7036022 |
1 |
11,300 |
179,400 |
106,000 |
177 |
14,300 |
47,400 |
367 |
|
Y800020 |
233335 |
7036022 |
20 |
11,400 |
181,150 |
107,000 |
177 |
14,500 |
48,300 |
375 |
|
Y800022 |
233335 |
7036022 |
35 |
11,400 |
181,150 |
107,000 |
179 |
14,800 |
48,900 |
376 |
APPENDIX 2 – JORC TABLE ONE
Section 1: Sampling Techniques and Data
|
Criteria |
JORC Code explanation |
Commentary |
|
Sampling techniques |
Nature and quality of sampling (eg cut channels, random chips, or specific specialised industry standard measurement tools appropriate to the minerals under investigation, such as down hole gamma sondes, or handheld XRF instruments, etc). These examples should not be taken as limiting the broad meaning of sampling. Include reference to measures taken to ensure sample representivity and the appropriate calibration of any measurement tools or systems used. Aspects of the determination of mineralisation that are Material to the Public Report. In cases where ‘industry standard’ work has been done this would be relatively simple (eg ‘reverse circulation drilling was used to obtain 1 m samples from which 3 kg was pulverised to produce a 30 g charge for fire assay’). In other cases more explanation may be required, such as where there is coarse gold that has inherent sampling problems. Unusual commodities or mineralisation types (eg submarine nodules) may warrant disclosure of detailed information. |
Brine samples were collected from Williamson Pit at various depths. |
|
Drilling techniques |
Drill type (eg core, reverse circulation, open-hole hammer, rotary air blast, auger, Bangka, sonic, etc) and details (eg core diameter, triple or standard tube, depth of diamond tails, face-sampling bit or other type, whether core is oriented and if so, by what method, etc). |
Not applicable
|
|
Drill sample recovery |
Method of recording and assessing core and chip sample recoveries and results assessed. Measures taken to maximise sample recovery and ensure representative nature of the samples. Whether a relationship exists between sample recovery and grade and whether sample bias may have occurred due to preferential loss/gain of fine/coarse material. |
Not applicable
|
|
Logging |
Whether core and chip samples have been geologically and geotechnically logged to a level of detail to support appropriate Mineral Resource estimation, mining studies and metallurgical studies. Whether logging is qualitative or quantitative in nature. Core (or costean, channel, etc) photography. The total length and percentage of the relevant intersections logged. |
Not applicable
|
|
Sub-sampling techniques and sample preparation |
If core, whether cut or sawn and whether quarter, half or all core taken. If non-core, whether riffled, tube sampled, rotary split, etc and whether sampled wet or dry. For all sample types, the nature, quality and appropriateness of the sample preparation technique. Quality control procedures adopted for all sub-sampling stages to maximise representivity of samples. Measures taken to ensure that the sampling is representative of the in situ material collected, including for instance results for field duplicate/second-half sampling. Whether sample sizes are appropriate to the grain size of the material being sampled. |
Sample bottles are rinsed with brine which is discarded prior to sampling. All brine samples taken in the field are split into two sub-samples: primary and duplicate. Reference samples were analysed at a separate laboratory for QA/QC.
|
|
Quality of assay data and laboratory tests |
The nature, quality and appropriateness of the assaying and laboratory procedures used and whether the technique is considered partial or total. For geophysical tools, spectrometers, handheld XRF instruments, etc, the parameters used in determining the analysis including instrument make and model, reading times, calibrations factors applied and their derivation, etc. Nature of quality control procedures adopted (eg standards, blanks, duplicates, external laboratory checks) and whether acceptable levels of accuracy (ie lack of bias) and precision have been established. |
Primary samples were sent to Bureau Veritas Minerals Laboratory, Perth. Brine samples were analysed using ICP-AES for K, Na, Mg, Ca, with chloride determined by Mohr titration and alkalinity determined volumetrically. Sulphate was calculated from the ICP-AES sulphur analysis.
|
|
Verification of sampling and assaying |
The verification of significant intersections by either independent or alternative company personnel. The use of twinned holes. Documentation of primary data, data entry procedures, data verification, data storage (physical and electronic) protocols. Discuss any adjustment to assay data. |
Data entry is done in the field to minimise transposition errors. Brine assay results are received from the laboratory in digital format, these data sets are subject to the quality control described above. All laboratory results are entered in to the company’s database and validation completed. Independent verification of significant intercepts was not considered warranted given the relatively consistent nature of the brine. |
|
Location of data points |
Accuracy and quality of surveys used to locate drill holes (collar and down-hole surveys), trenches, mine workings and other locations used in Mineral Resource estimation. Specification of the grid system used. Quality and adequacy of topographic control. |
Sample co-ordinates were captured using hand held GPS. Coordinates were provided in GDA 94_MGA Zone 51. product.
|
|
Data spacing and distribution |
Data spacing for reporting of Exploration Results. Whether the data spacing and distribution is sufficient to establish the degree of geological and grade continuity appropriate for the Mineral Resource and Ore Reserve estimation procedure(s) and classifications applied. Whether sample compositing has been applied. |
Data spacing reported in Appendix 1
|
|
Orientation of data in relation to geological structure |
Whether the orientation of sampling achieves unbiased sampling of possible structures and the extent to which this is known, considering the deposit type. If the relationship between the drilling orientation and the orientation of key mineralised structures is considered to have introduced a sampling bias, this should be assessed and reported if material. |
Not Applicable
|
|
Sample security |
The measures taken to ensure sample security. |
All brine samples were marked and kept onsite before transport to the laboratory. All remaining sample and duplicates are stored in the Perth office in climate-controlled conditions. Chain of Custody system is maintained. |
|
Audits or reviews |
The results of any audits or reviews of sampling techniques and data. |
Data review is summarised in Quality of assay data, laboratory tests and Verification of sampling and assaying. No audits were undertaken. |
Section 2: Reporting of Exploration Results
|
Criteria |
JORC Code explanation |
Commentary |
|
Mineral tenement and land tenure status |
Type, reference name/number, location and ownership including agreements or material issues with third parties such as joint ventures, partnerships, overriding royalties, native title interests, historical sites, wilderness or national park and environmental settings. The security of the tenure held at the time of reporting along with any known impediments to obtaining a licence to operate in the area.
|
Pit samples were taken from M53/253 owned by Blackham Resources Limited (held by Nova Energy Ltd) under the permission of Blackham Resources Limited. |
|
Exploration done by other parties |
Acknowledgment and appraisal of exploration by other parties. |
Addressed in the announcement dated 12 December 2017. |
|
Geology |
Deposit type, geological setting and style of mineralisation. |
Salt Lake Brine Deposit |
|
Drill hole Information |
A summary of all information material to the understanding of the exploration results including a tabulation of the following information for all Material drill holes: o easting and northing of the drill hole collar o elevation or RL (Reduced Level – elevation above sea level in metres) of the drill hole collar o dip and azimuth of the hole o down hole length and interception depth o hole length. If the exclusion of this information is justified on the basis that the information is not Material and this exclusion does not detract from the understanding of the report, the Competent Person should clearly explain why this is the case. |
Not Applicable
|
|
Data aggregation methods |
In reporting Exploration Results, weighting averaging techniques, maximum and/or minimum grade truncations (eg cutting of high grades) and cut-off grades are usually Material and should be stated. Where aggregate intercepts incorporate short lengths of high grade results and longer lengths of low grade results, the procedure used for such aggregation should be stated and some typical examples of such aggregations should be shown in detail. The assumptions used for any reporting of metal equivalent values should be clearly stated. |
No low grade cut-off or high grade capping has been implemented.
|
|
Relationship between mineralisation widths and intercept lengths |
These relationships are particularly important in the reporting of Exploration Results. If the geometry of the mineralisation with respect to the drill hole angle is known, its nature should be reported. If it is not known and only the down hole lengths are reported, there should be a clear statement to this effect (eg ‘down hole length, true width not known’). |
Not applicable |
|
Diagrams |
Appropriate maps and sections (with scales) and tabulations of intercepts should be included for any significant discovery being reported These should include, but not be limited to a plan view of drill hole collar locations and appropriate sectional views. |
Not Applicable |
|
Balanced reporting |
Where comprehensive reporting of all Exploration Results is not practicable, representative reporting of both low and high grades and/or widths should be practiced to avoid misleading reporting of Exploration Results. |
All results have been included. |
|
Other substantive exploration data |
Other exploration data, if meaningful and material, should be reported including (but not limited to): geological observations; geophysical survey results; geochemical survey results; bulk samples – size and method of treatment; metallurgical test results; bulk density, groundwater, geotechnical and rock characteristics; potential deleterious or contaminating substances. |
Addressed in the announcement.
|
|
Further work |
The nature and scale of planned further work (eg tests for lateral extensions or depth extensions or large-scale step-out drilling). Diagrams clearly highlighting the areas of possible extensions, including the main geological interpretations and future drilling areas, provided this information is not commercially sensitive. |
Addressed in the announcement.
|
For further information please visit www.saltlakepotash.com.au or contact:
|
Matt Syme/Sam Cordin |
Salt Lake Potash Limited |
Tel: +61 8 9322 6322 |
|
Jo Battershill |
Salt Lake Potash Limited |
Tel: +44 (0) 20 7478 3900 |
|
Colin Aaronson/Richard Tonthat |
Grant Thornton UK LLP (Nominated Adviser) |
Tel: +44 (0) 20 7383 5100 |
|
Derrick Lee/Beth McKiernan |
Cenkos Securities plc (Joint Broker) |
Tel: +44 (0) 131 220 6939 |
|
Jerry Keen/Toby Gibbs
|
Shore Capital (Joint broker) |
Tel: +44 (0) 20 7468 7967
|
The information contained within this announcement is deemed to constitute inside information as stipulated under the Market Abuse Regulations (EU) No. 596/2014. Upon the publication of this announcement, this inside information is now considered to be in the public domain.
Salt Lake Potash #SO4 – December 2017 Quarterly Report
The Board of Salt Lake Potash Limited (the Company or SLP) is pleased to present its Quarterly Report for the period ending 31 December 2017.
Highlights for the quarter and subsequently include:
LAKE WELLS
Evaporation Pond Testwork
Ø The Company successfully completed field testing of its on-lake, unlined evaporation pond model, which will result in significant capital cost advantages for the Goldfields Salt Lakes Project (GSLP).
Ø Comprehensive geological and geotechnical investigation confirms the widespread availability of ideal in-situ clay materials ideal for use in evaporation pond construction. Modelling based on geotechnical properties of the clays confirms the potential to build unlined, on-lake ponds with negligible seepage inefficiency.
Ø Amec Foster Wheeler estimate that comparative costs for 400ha of on-lake ponds are $1.6m (unlined) and $42.2m (HDPE lined), highlighting a significant capex advantage for the Project.
Process Testwork
Ø The Site Evaporation Trial (SET) at Lake Wells has now processed approximately 357 tonnes of brine and produced over 8 tonnes of harvest salts.
Ø The Company continued process development testwork at globally recognised potash process consultants, Saskatchewan Research Council (SRC). SRC began a continuous locked cycle testing of the proposed Lake Wells process to demonstrate the Sulphate of Potash (SOP) production process from salt harvested from the SET.
Ø The SRC locked cycle tests will also produce significant quantities of flotation product and SOP for further testing and marketing.
Surface Aquifer Characterisation and Deep Aquifer Exploration
Ø The Company continued sustained pump tests on test trenches across Lake Wells, providing reliable data for the surface aquifer hydrogeological model.
Ø The Company completed an on-lake drill program to test deep aquifer characteristics and identify potential high yield portions of the basal aquifer.
Demonstration Plant
Ø The Company and its consultants have substantially advanced the Demonstration Plant study for the GSLP.
LAKE IRWIN
Ø An initial surface aquifer exploration program was completed at Lake Irwin, comprising a total of 27 shallow test pits and 2 test trenches. This work provides preliminary data for the geological and hydrological models of the surface aquifer of the Lake, as well as brine, geological and geotechnical samples.
LAKE WAY
Ø The Company conducted an initial reconnaissance surface sampling program at Lake Way in November 2017, with brine samples averaging 15kg/m3 of SOP equivalent. In conjunction with extensive historical exploration data, these results indicate excellent potential for Lake Way to host a large high-grade SOP brine resource.
REGIONAL LAKES
Ø The Company undertook initial surface brine sampling of the near surface aquifer and reconnaissance of access and infrastructure at all remaining Lakes held under the GSLP.
The Company’s primary focus is to construct a Demonstration Plant at the GSLP, intended to be the first salt-lake brine SOP production operation in Australia. While proceeding with the analysis of options to construct a SOP Demonstration Plant at Lake Wells, the Company is also exploring the other lakes in the GSLP.
GOLDFIELDS SALT LAKES PROJECT
The Company’s primary focus is to construct a Demonstration Plant at the GSLP, intended to be the first salt-lake brine SOP production operation in Australia. While proceeding with the analysis of options to construct a SOP Demonstration Plant at Lake Wells, the Company is also exploring the other lakes in the GSLP.
The Company achieved a very important milestone of completing successful validation of the final major technical foundations for production of Sulphate of Potash (SOP) from the GSLP.
While proceeding with a Pre-Feasibility Study (PFS) for Lake Wells, the Company has also completed initial surface sampling and reconnaissance work across all of the other regional Lakes in the GSLP.
The GSLP’s lakes have been selected for:
· scale and potential brine volume;
· known hypersaline brine characteristics;
· potential for both shallow trench extraction and from deeper paleochannel aquifer bores;
· large playa surface for cost-effective evaporation pond construction; and
· proximity to the important transport and energy infrastructure and engineering expertise available in the Western Australian Goldfields.
While all of the lakes comprising the GSLP share the advantage of their location in the WA Goldfields, it is worth noting that several of the lakes are even closer to rail transport and the gas pipeline than Lake Wells. For example, Lake Ballard and Lake Marmion are located either side of the Goldfields Highway, gas pipeline and rail line, only 140km from the major mining service centre of Kalgoorlie.
There is substantial potential for integration, economies of scale, operating synergies and overhead sharing in the GSLP due to the number of highly prospective lakes. The flexibility of multi-lake production is also appealing for a natural production process which is subject to climate variability.
The Company will study these advantages more closely as it progresses the Goldfields Salt Lakes Project.
LAKE WELLS
Evaporation Ponds Construction Trial
The Company completed an evaporation pond construction trial at Lake Wells. The field trial involved construction and testing of four test ponds on the Lake Wells Playa, built solely from in-situ clay materials, using a standard 30t excavator, which operated efficiently and effectively on the lake playa. The trial achieved levels of brine seepage from the evaporation ponds well below the threshold for successful operation of halite evaporation ponds, and potentially also for the smaller potassium salt harvest ponds. (for complete details see Stock Exchange announcement dated 16 October 2017)
The capex savings from this construction method are substantial, compared to the alternative of plastic lined ponds. SLP’s engineering consultant, Amec Foster Wheeler, estimates the cost of lined ponds to be approximately $10.50 per m2, up to 25 times higher than construction costs for unlined ponds.
The 25m x 25m test ponds were designed by SLP’s geotechnical consultant, MHA Geotechnical (MHA), to test the constructability and operating performance of a number of pond wall designs and to provide reliable seepage data under site conditions. The observed brine loss in the test ponds was well within the parameters of the hydrodynamic model, indicating losses for a 400ha pond will be below 0.125mm/day.
The Company has identified several opportunities to improve the construction of commercial scale ponds using excavators, along with ancillary equipment to optimize drying and compaction of the clays utilized in pond wall construction. This should result in further improvements in the already very low seepage observed in the trial sized ponds.
SLP plans to now construct a Pilot scale pond system to further improve the pond design and construction model.
Test Pond Results
Test Pond 3 (TP3) represents the as-modelled embankment construction and is the most likely design for commercial scale embankments. A total of 32 piezometric standpipes and 12 water data loggers were installed in and around all four walls of TP3, along with water level measuring devices on the floor of the pond and in the surrounding trenches, to accurately measure the water levels both in the pond and within the embankments.
The embankment and key are constructed from clay which was air-dried prior to compaction to ensure target compaction and permeability are achieved. After the embankment and key material is saturated, the seepage from the pond, net of brine evaporation (data from the control pond) represents seepage losses through and below the pond walls. Net seepage losses of less than 3mm per day at test pond scale would substantially validate the shallow lake lithology, geotechnical characteristics and pond construction model for production scale, clay lined, on-lake halite evaporation ponds.
TP3 was initially filled with lake brine to approximately 500mm on 29 August 2017. The small, plastic lined, control pond was also filled to provide an accurate measure of evaporation rates.
Water level and piezometer readings were taken twice daily since and on 18 September 2017 the ponds were topped up, TP3 to approximately 1,000mm in this case, to accelerate wall saturation.
From the initial brine fill, the average net seepage at TP3 equated to approximately 2.4mm per day. This figure includes “losses” to wall saturation as well as to seepage, indicating that steady state seepage losses were comfortably below the 3mm per day threshold modelled for this scale of pond.
Capital Cost Comparison
The Company’s engineering consultants, Amec Foster Wheeler, generated scoping level cost estimates comparing two pond construction options for a 400ha halite pond. For ponds built on-lake on a relatively flat playa, with no provision for salt harvesting, and a 2.0m high wall, Amec Foster Wheeler estimate direct capital costs (accuracy of -10%/+30%) of:
· Unlined – A$1.6m
· Lined – A$42.2m
The main costs of the lined ponds are the supply and installation of HDPE lining and placement and compaction of a sand bedding layer. If similar ponds were constructed off lake then clearing and levelling costs would be additional.
For either lined or unlined ponds, if salt harvesting is required a layer of halite must first be deposited and compacted, to provide a support base for harvesting equipment. As the Company does not plan to harvest halite from its ponds, these costs are not included in the Amec Foster Wheeler analysis.
Process Testwork
The Company continues a range of process development testwork to enhance the Lake Wells process model.
Site Evaporation Trial
A large scale, continuous Site Evaporation Trial (SET) at Lake Wells successfully completed 15 months of operation under site conditions and through all seasons, confirming the solar evaporation pathway for production of potassium rich harvest salts for processing into SOP. The objective of the SET was to refine process design criteria for the halite evaporation ponds and subsequent harvest salt ponds.
The SET has processed approximately 357 tonnes of Lake Wells brine and produced 8.1 tonnes of harvest salts.
The results of the SET are Australian first and have provided significant knowledge to the Company on the salt crystallisation pathway under site conditions in Australia.
During the quarter, approximately 122t of Lake Wells brine was processed through both trains of the SET, producing approximately 2,600kg of harvest salt at average potassium grades within target parameters. Production levels increased as the temperature (evaporation rates) increased with daily evaporation reaching levels of above 16mm/day.
The large quantity of salt produced via the SET is available for larger scale production of commercial samples for potential customers and partners around the world.
Process Testwork – Saskatchewan Research Council (SRC)
SRC has been engaged to carry out further optimisation tests to validate and duplicate the results achieved to date, followed by a locked-cycle continuous production test to quantify brine handling requirements and obtain product purity information on a continuous basis.
The locked-cycle test will also provide a significant quantity of flotation product to allow crystalliser vendor testing, design work, and product for testing and commercial purposes.
The locked-cycle testwork was completed in late December and final results will be available shortly.
Surface Aquifer Characterisation Program
The Company has completed a substantial program of work investigating the geological and hydrogeological attributes of the Shallow Lake Bed Sediment hosted brine resource at Lake Wells. The information and data generated will be utilised in the design of the brine extraction system for the GSLP Pilot Plant.
The total program includes 250 test pits and 10 trenches over the lake playa. The test pits are generally 1m wide x 1.5m long and 4.5m deep and confirm lithology and permeability of upper lake bed sediments and demonstrate spatial continuity of the surface aquifer.
Long Term Test Pumping
The Company continued sustained pump tests on test trenches across Lake Wells. This work provides reliable data for the preparation of a surface aquifer hydrogeological model for Lake Wells.
The testing was conducted as a “constant head test” whereby flow rate was adjusted to maintain a constant trench water level. Drawdown was observed at nearby observation bores placed at distances of 10m, 20m and 50m from the trench.
Trench dimensions and pumping test results are presented in Table 1. Trench length varied from 25m to 125m length. Trench depth was constrained by the capacity of the excavator and the stability of the ground conditions and ranged from 2m to 6m below ground surface. Aquifer properties were estimated from the trench test data by calibration of a flow model for each trench.
Flow rates toward the end of testing ranged from 13 to 517m3/day. Higher flow rates are associated with evaporite deposits in the Playa Sediments.
These results are very encouraging and continue to support the design of the SOP operation at Lake Wells.
|
Trench |
Average Depth |
Trench Length |
Test Duration |
Total Volume Pumped |
Average Pumping Rate |
Final Pumping Rate |
Calculated |
Calc. |
Brine Chemistry |
|
(m) |
(m) |
(days) |
(m3) |
(m3/day) |
(m3/day) |
(m2/day) |
(K mg/L) |
||
|
P1a |
4.5 |
25 |
8.3 |
557 |
65 |
54 |
13.5 |
0.10 |
– |
|
P1b |
2 |
25 |
Not tested |
||||||
|
P1c |
4.5 |
50 |
7.3 |
673 |
170 |
127 |
96 |
0.07 |
5,673 |
|
P1c |
4.5 |
50 |
Long-term test in progress |
||||||
|
P1e |
3.5 |
125 |
25 |
1,878 |
105 |
82 |
24 |
0.13 |
5,600 |
|
P1g |
4 |
10 |
9.6 |
199 |
21 |
21 |
26 |
0.28 |
4,620 |
|
P1h |
6 |
125 |
Long-term test in progress |
||||||
|
P2a |
2.2 |
25 |
9.7 |
272 |
28 |
31 |
46 |
0.25 |
6,055 |
|
P2b |
2.8 |
25 |
7 |
378 |
54 |
25 |
7 |
0.14 |
4,762 |
|
P2c |
3.5 |
25 |
10 |
638 |
64 |
50 |
174 |
0.25 |
4,355 |
|
P3b |
4 |
50 |
7 |
3,831 |
547 |
517 |
231 |
0.25 |
4,311 |
|
P3c |
4 |
50 |
10 |
95 |
13 |
13 |
1 |
0.14 |
5,474 |
Table 1: Summary of Trench Test Pumping
Brine chemistry was consistent throughout the duration of the tests.
The Company is continuing extended pump tests on test trenches across Lake Wells with two long-term tests currently underway. These pumping tests will run for over 60 days to continue to validate the hydrology model and provide additional data on the draw down, recharge and brine concentration during extended pumping.
Deep Aquifer Exploration Program
During the quarter, an on-lake deep aquifer exploration diamond core drill program was undertaken, investigating paleochannel aquifer targets identified by geophysical survey. The results will provide further understanding of the characteristics of the paleochannel aquifer and identified locations for further test pumping bores to advance and refine the Lake Wells hydrogeological model.
Five observation bores ranging between 42m and 130m deep were completed across the Lake. The bores were constructed with 80mm PVC casing (internal diameter) through the paleochannel sediments to enable more investigations such as airlifting tests and possible downhole geophysical surveys.
The bores encountered the expected sequence of surficial alluvium to an average depth of 20m followed by up to 70m thick sequence of lacustrine clays before intersecting the paleochannel sediments. Some of the bores were targeted to drill through the paleochannel sediments into the Proterozoic Basement where it was fractured by geological faults.
The drilling results indicated that the modelled gravimetric and passive seismic interpretations were very accurate in locating the elevation of the basement as well as confirming the shape of the paleochannel. The addition of the airborne magnetic lineaments indicated zones where the basement underlying the paleochannel is weathered and fractured by faulting. This provided good targets to drill through the paleochannel sediments into the fractured basement.
Airlift testing of the observation bores is underway with the purpose of measuring aquifer properties.
Demonstration Plant
As previously announced, Amec Foster Wheeler have been engaged to prepare an analysis of the alternatives for the Company to construct a Demonstration Plant at the GSLP.
International brine and salt processing experts Carlos Perucca Processing Consulting Ltd (CPPC) and AD Infinitum Ltd (AD Infinitum) are also engaged for the Study.
Substantial progress continues on pond and trench design, mass balance modelling, process flowsheet design, major equipment quotations, costings and transportation studies.
LAKE IRWIN
Surface Aquifer Exploration Program
An initial surface aquifer exploration program was undertaken at Lake Irwin, comprising a total of 27 test pits and 2 test trenches. The test trenches were 100m long and constructed to a depth of 4-5 meters.
This work provides preliminary data for the hydrogeological model for the surface aquifer of the Lake, geological and geotechnical information for the upper strata of the Lake and deeper brine samples than previously available.
The 27 test pits completed across both the north and south of Lake Irwin. The geology and associated hydrology of the shallow (recent lacustrine) sediments is similar to that identified at Lake Wells.
A surface layer (up to 0.8m thick) of evaporitic (crystallised gypsum) sand typically overlies a red clay unit that is up to several meters thick. Thin beds and lenses of evaporitic sand also tended to exist at various depths within the red clay unit. Rapid inflow of brine occurred into the test pits and trenches from the surface, evaporitic sand unit and from the beds and lenses within the lower clay unit.
Bedded silica sands were identified at depths greater than two meters in the Northern lobe of the lake. Rapid inflow of brine was observed from this underlying, inferred fluvial (riverine) unit. This unit is very encouraging for future exploration programs.
Brine was sampled during the excavation process. Potassium grades from 26 assays from the test pits ranged from 1,550 to 3,290mg/L. The data are presented as Appendix 4.
|
Number of Samples |
K (mg/L) |
Mg (mg/L) |
SO4 (mg/L) |
SOP* (kg/m3) |
|
|
Northern Lobe |
4 |
3,033 |
5,760 |
22,650 |
6.76 |
|
Southern Lobe |
22 |
2,102 |
2,725 |
11,012 |
4.69 |
* Conversion factor of K to SOP (K2SO4 equivalent) is 2.23
Table 2: Lake Irwin Brine Chemistry split between the Northern and Southern Lobes
Four large geotechnical samples of 20kg each were taken from the main identified aquifer units. These samples will be processed to assess geotechnical and hydrogeological parameters for the different geological units in the profile, continuing the Company’s assessment of brine extraction potential via trenching, as well as assessing the suitability of the clay lithologies for pond construction. Initial visual interpretation during the excavation process indicated excellent stratigraphy and geotechnical potential similar to results at Lake Wells.
LAKE WAY
Reconnaissance and Pit Sampling Program
The Company conducted an initial reconnaissance surface sampling program at Lake Way in November 2017. A total of 8 pit samples were collected at Lake Way encountering brine at a standing water level from less than 1 metre from surface. The average brine chemistry of the samples was:
|
Brine Chemistry |
K |
Mg |
SO4 |
TDS |
SOP* |
|
(mg/L) |
(mg/L) |
(mg/L) |
(mg/L) |
(kg/m3)
|
|
|
Surface Sampling (average 8 samples) |
6,859 |
7,734 |
25,900 |
243,000 |
15.25 |
* Conversion factor of K to SOP (K2SO4 equivalent) is 2.23
Table 3: Lake Way Brine Chemistry from Surface Sampling
Exploration History
Significant historical exploration work has been completed in the Lake Way area focusing on nickel, gold and uranium. The Company has reviewed multiple publicly available documents including relevant information on the Lake Way’s hydrogeology and geology.
The Lake Way drainage is incised into the Archean basement and now in-filled with a mixed sedimentary sequence, the paleochannel sands occurring only in the deepest portion. The mixed sediments include sand, silts and clays of lacustrine, aeolin, fluvial and colluvial depositional origins. The surficial deposits also include chemical sediments comprising calcrete, silcrete and ferricrete. The infill sediments provide a potential reservoir for large quantities of groundwater.
Groundwater exploration was undertaken in the early 1990s by AGC Woodward Clyde[1] to locate and secure a process water supply for WMC Resources Limited’s Mt Keith nickel operation. There was a wide and extensive program of exploration over 40 km of palaeodrainage that focused on both the shallow alluvium and deeper palaeochannel aquifers.
The comprehensive drilling program comprised 64 air-core drillholes totalling 4,336m and five test production bores (two of which were within SLP’s exploration licences). The aquifers identified were a deep palaeochannel sand unit encountered along the length of the Lake Way investigation area and a shallow aquifer from surface to a depth of approximately 30m.
The shallow aquifer comprises a mixture of alluvium, colluvium and lake sediments extending beyond the lake playa and continuing downstream. Bore yields from Constant Rate Tests (CRT) in the shallow aquifer ranged from 60kL/day up to 590kL/day in permeable coarse-grained sand.
The deep palaeochannel sand aquifer is confined beneath plasticine clay up to 70m thick. The sand comprises medium to coarse grained quartz grains with little clay – it is approximately 30m thick and from 400m to 900m in width. Five test production bores were developed, of which two are within SLP’s tenements. CRT bore yields ranged from 520kL/day up to 840kL/day in permeable coarse-grained sand.
The groundwater is hypersaline and saturated near the lake surface with concentrations declining away from the lake. In the production bores within the SLP tenement, the reported potassium concentration was up to 4,000 mg/L K in the shallow aquifer and up to 6,300 mg/L K in the deep aquifer.
Competent Persons Statement
The information in this report that relates to Exploration Results, or Mineral Resources for Lake Wells and Lake Irwin is based on information compiled by Mr Ben Jeuken, who is a member Australian Institute of Mining and Metallurgy. Mr Jeuken is employed by Groundwater Science Pty Ltd, an independent consulting company. Mr Jeuken has sufficient experience, which is relevant to the style of mineralisation and type of deposit under consideration and to the activity, which he is undertaking to qualify as a Competent Person as defined in the 2012 Edition of the ‘Australasian Code for Reporting of Exploration Results, Mineral Resources and Ore Reserves’. Mr Jeuken consents to the inclusion in the report of the matters based on his information in the form and context in which it appears.
The information in this Announcement that relates to Exploration Results for Lake Way is extracted from the report entitled ‘Emerging World Class SOP Potential Supported By Lake Way’ dated 12 December 2017. The information in the original ASX Announcement that related to Exploration Results, for Lake Way is based on information compiled by Mr Ben Jeuken, who is a member Australian Institute of Mining and Metallurgy. Mr Jeuken is employed by Groundwater Science Pty Ltd, an independent consulting company. Mr Jeuken has sufficient experience, which is relevant to the style of mineralisation and type of deposit under consideration and to the activity, which he is undertaking to qualify as a Competent Person as defined in the 2012 Edition of the ‘Australasian Code for Reporting of Exploration Results, Mineral Resources and Ore Reserves’. Mr Jeuken consents to the inclusion in the report of the matters based on his information in the form and context in which it appears. The Company confirms that it is not aware of any new information or data that materially affects the information included in the original market announcement. The Company confirms that the form and context in which the Competent Person’s findings are presented have not been materially modified from the original market announcement
The information in this report that relates to Process Testwork Results is based on, and fairly represents, information compiled by Mr Bryn Jones, BAppSc (Chem), MEng (Mining) who is a Fellow of the AusIMM, a ‘Recognised Professional Organisation’ (RPO) included in a list promulgated by the ASX from time to time. Mr Jones is a Director of Salt Potash Limited. Mr Jones has sufficient experience, which is relevant to the style of mineralisation and type of deposit under consideration and to the activity which he is undertaking, to qualify as a Competent Person as defined in the 2012 Edition of the ‘Australasian Code for Reporting of Exploration Results, Mineral Resources and Ore Reserves’. Mr Jones consents to the inclusion in the report of the matters based on his information in the form and context in which it appears.
Table 4 – Summary of Exploration and Mining Tenements
As at 31 December 2017, the Company holds interests in the following tenements:
Australian Projects:
|
Project |
Status |
Type of Change |
License Number |
Area (km2) |
Term |
Grant Date |
Date of First Relinquish-ment |
Interest (%) 1-Oct-17 |
Interest (%) 31-Dec-17 |
||||||
|
Western Australia |
|||||||||||||||
|
Lake Wells |
|||||||||||||||
|
Central |
Granted |
– |
E38/2710 |
192.2 |
5 years |
05-Sep-12 |
4-Sep-17 |
100% |
100% |
||||||
|
South |
Granted |
– |
E38/2821 |
131.5 |
5 years |
19-Nov-13 |
18-Nov-18 |
100% |
100% |
||||||
|
North |
Granted |
– |
E38/2824 |
198.2 |
5 years |
04-Nov-13 |
3-Nov-18 |
100% |
100% |
||||||
|
Outer East |
Granted |
– |
E38/3055 |
298.8 |
5 years |
16-Oct-15 |
16-Oct-20 |
100% |
100% |
||||||
|
Single Block |
Granted |
– |
E38/3056 |
3.0 |
5 years |
16-Oct-15 |
16-Oct-20 |
100% |
100% |
||||||
|
Outer West |
Granted |
– |
E38/3057 |
301.9 |
5 years |
16-Oct-15 |
16-Oct-20 |
100% |
100% |
||||||
|
North West |
Granted |
– |
E38/3124 |
39.0 |
5 years |
30-Nov-16 |
29-Nov-21 |
100% |
100% |
||||||
|
West |
Granted |
– |
L38/262 |
113.0 |
20 years |
3-Feb-17 |
2-Feb-38 |
100% |
100% |
||||||
|
East |
Granted |
– |
L38/263 |
28.6 |
20 years |
3-Feb-17 |
2-Feb-38 |
100% |
100% |
||||||
|
South West |
Granted |
– |
L38/264 |
32.6 |
20 years |
3-Feb-17 |
2-Feb-38 |
100% |
100% |
||||||
|
South |
Application |
– |
L38/287 |
95.8 |
– |
– |
– |
100% |
100% |
||||||
|
South Western |
Application |
– |
E38/3247 |
350.3 |
– |
– |
– |
100% |
100% |
||||||
|
South |
Application |
Application Lodged |
M38/1278 |
87.47 |
– |
– |
– |
– |
100% |
||||||
|
Lake Ballard |
|||||||||||||||
|
West |
Granted |
– |
E29/912 |
607.0 |
5 years |
10-Apr-15 |
10-Apr-20 |
100% |
100% |
||||||
|
East |
Granted |
– |
E29/913 |
73.2 |
5 years |
10-Apr-15 |
10-Apr-20 |
100% |
100% |
||||||
|
North |
Granted |
– |
E29/948 |
94.5 |
5 years |
22-Sep-15 |
21-Sep-20 |
100% |
100% |
||||||
|
South |
Granted |
– |
E29/958 |
30.0 |
5 years |
20-Jan-16 |
19-Jan-21 |
100% |
100% |
||||||
|
South East |
Granted |
– |
E29/1011 |
68.2 |
5 years |
11-Aug-17 |
10-Aug-22 |
100% |
100% |
||||||
|
South East |
Application |
– |
E29/1020 |
9.3 |
– |
– |
– |
100% |
100% |
||||||
|
South East |
Application |
– |
E29/1021 |
27.9 |
– |
– |
– |
100% |
100% |
||||||
|
South East |
Application |
– |
E29/1022 |
43.4 |
– |
– |
– |
100% |
100% |
||||||
|
Lake Irwin |
|||||||||||||||
|
West |
Granted |
– |
E37/1233 |
203.0 |
5 years |
08-Mar-16 |
07-Mar-21 |
100% |
100% |
||||||
|
Central |
Granted |
– |
E39/1892 |
203.0 |
5 years |
23-Mar-16 |
22-Mar-21 |
100% |
100% |
||||||
|
East |
Granted |
– |
E38/3087 |
139.2 |
5 years |
23-Mar-16 |
22-Mar-21 |
100% |
100% |
||||||
|
North |
Granted |
– |
E37/1261 |
107.3 |
5 years |
14-Oct-16 |
13-Oct-21 |
100% |
100% |
||||||
|
Central East |
Granted |
– |
E38/3113 |
203.0 |
5 years |
14-Oct-16 |
13-Oct-21 |
100% |
100% |
||||||
|
South |
Granted |
– |
E39/1955 |
118.9 |
5 years |
14-Oct-16 |
13-Oct-21 |
100% |
100% |
||||||
|
North West |
Application |
– |
E37/1260 |
203.0 |
– |
– |
– |
100% |
100% |
||||||
|
South West |
Application |
– |
E39/1956 |
110.2 |
– |
– |
– |
100% |
100% |
||||||
|
Lake Minigwal |
|||||||||||||||
|
West |
Granted |
– |
E39/1893 |
246.2 |
5 years |
01-Apr-16 |
31-Mar-21 |
100% |
100% |
||||||
|
East |
Granted |
– |
E39/1894 |
158.1 |
5 years |
01-Apr-16 |
31-Mar-21 |
100% |
100% |
||||||
|
Central |
Granted |
– |
E39/1962 |
369.0 |
5 years |
8-Nov-16 |
7-Nov-21 |
100% |
100% |
||||||
|
Central East |
Granted |
– |
E39/1963 |
93.0 |
5 years |
8-Nov-16 |
7-Nov-21 |
100% |
100% |
||||||
|
South |
Granted |
– |
E39/1964 |
99.0 |
5 years |
8-Nov-16 |
7-Nov-21 |
100% |
100% |
||||||
|
South West |
Application |
– |
E39/1965 |
89.9 |
– |
– |
– |
100% |
100% |
||||||
|
Lake Way |
|||||||||||||||
|
Central |
Granted |
– |
E53/1878 |
217.0 |
5 years |
12-Oct-16 |
11-Oct-21 |
100% |
100% |
||||||
|
South |
Application |
– |
E53/1897 |
77.5 |
– |
– |
– |
100% |
100% |
||||||
|
Lake Marmion |
|||||||||||||||
|
North |
Granted |
– |
E29/1000 |
167.4 |
5 years |
03-Apr-17 |
02-Apr-22 |
100% |
100% |
||||||
|
Central |
Granted |
– |
E29/1001 |
204.6 |
5 years |
03-Apr-17 |
02-Apr-22 |
100% |
100% |
||||||
|
South |
Granted |
– |
E29/1002 |
186.0 |
5 years |
15-Aug-17 |
14-Aug-22 |
100% |
100% |
||||||
|
West |
Granted |
– |
E29/1005 |
68.2 |
5 years |
11-Jul-17 |
10-Jul-22 |
100% |
100% |
||||||
|
Lake Noondie |
|||||||||||||||
|
North |
Application |
– |
E57/1062 |
217.0 |
– |
– |
– |
100% |
100% |
||||||
|
Central |
Application |
– |
E57/1063 |
217.0 |
– |
– |
– |
100% |
100% |
||||||
|
South |
Application |
– |
E57/1064 |
55.8 |
– |
– |
– |
100% |
100% |
||||||
|
West |
Application |
– |
E57/1065 |
120.9 |
– |
– |
– |
100% |
100% |
||||||
|
East |
Application |
Application Lodged |
E36/932 |
108.5 |
– |
– |
– |
– |
100% |
||||||
|
Lake Barlee |
|||||||||||||||
|
North |
Application |
– |
E49/495 |
217.0 |
– |
– |
– |
100% |
100% |
||||||
|
Central |
Granted |
Granted |
E49/496 |
220.1 |
5 years |
17-Dec-17 |
16-Dec-22 |
100% |
100% |
||||||
|
South |
Granted |
Granted |
E77/2441 |
173.6 |
5 years |
09-Oct-17 |
08-Oct-22 |
100% |
100% |
||||||
|
Lake Raeside |
|||||||||||||||
|
North |
Application |
– |
E37/1305 |
155.0 |
– |
– |
– |
100% |
100% |
||||||
|
Northern Territory |
|||||||||||||||
|
Lake Lewis |
|||||||||||||||
|
South |
Granted |
– |
EL 29787 |
146.4 |
6 years |
08-Jul-13 |
7-Jul-19 |
100% |
100% |
||||||
|
North |
Granted |
– |
EL 29903 |
125.1 |
6 years |
21-Feb-14 |
20-Feb-19 |
100% |
100% |
||||||
APPENDIX 1 – LAKE WELLS DRILL LOCATION DATA
|
Hole_ID |
Drilled Depth (m) |
East |
North |
RL |
Dip |
Azimuth |
|
(mAHD) |
||||||
|
LWDD001 |
126.5 |
534271 |
7035995 |
443 |
-90 |
0 |
|
LWDD002 |
130.9 |
533930 |
7035793 |
443 |
-90 |
0 |
|
LWDD003 |
40.1 |
528670 |
7042963 |
443 |
-90 |
0 |
|
LWDD004 |
6 |
529637 |
7044808 |
443 |
-90 |
0 |
|
LWDD005 |
134.5 |
529382 |
7044461 |
443 |
-90 |
0 |
|
LWDD006 |
134.6 |
542285 |
6997220 |
443 |
-90 |
0 |
APPENDIX 2 – LAKE WELLS BRINE CHEMISTRY ANALYSIS
|
HOLE ID |
From (m) |
To (m) |
K (mg/L) |
Cl (mg/L) |
Na (mg/L) |
Ca (mg/L) |
Mg (mg/L) |
SO4 (mg/L) |
TDS (g/L) |
|
LWDD001 |
0 |
126.5 |
4,260 |
147,700 |
86,200 |
538 |
6,690 |
19,600 |
274 |
|
LWDD001 |
0 |
126.5 |
4,270 |
148,050 |
86,500 |
545 |
6,670 |
19,800 |
273 |
|
LWDD001 |
0 |
126.5 |
4,280 |
148,250 |
88,800 |
551 |
6,770 |
20,000 |
278 |
|
LWDD002 |
0 |
130.9 |
4,580 |
149,150 |
89,500 |
557 |
6,840 |
20,400 |
278 |
|
LWDD003 |
0 |
40.1 |
3,560 |
145,450 |
87,100 |
532 |
7,440 |
22,000 |
276 |
|
LWDD006 |
0 |
134.6 |
4,380 |
140,850 |
83,000 |
675 |
6,520 |
18,100 |
259 |
|
LWDD006 |
0 |
134.6 |
4,220 |
138,050 |
85,200 |
665 |
6,590 |
18,600 |
258 |
|
Trench P1c |
0 |
4.5 |
6,770 |
188,850 |
108,000 |
458 |
6,790 |
15,700 |
336 |
|
Trench P1c |
0 |
4.5 |
6,990 |
190,300 |
110,000 |
469 |
6,940 |
16,300 |
337 |
|
Trench P1c |
0 |
4.5 |
5,890 |
178,300 |
106,000 |
616 |
6,060 |
14,300 |
316 |
|
Trench P1c |
0 |
4.5 |
7,000 |
190,650 |
112,000 |
448 |
7,030 |
16,600 |
338 |
|
Trench P1c |
0 |
4.5 |
5,430 |
168,300 |
98,000 |
671 |
5,680 |
13,700 |
299 |
|
Trench P1h |
0 |
6.0 |
5,030 |
160,200 |
95,900 |
660 |
6,040 |
14,500 |
290 |
|
Trench P1h |
0 |
6.0 |
4,990 |
160,750 |
94,600 |
669 |
6,000 |
14,600 |
290 |
|
Trench P1h |
0 |
6.0 |
5,000 |
159,150 |
95,800 |
710 |
6,080 |
14,700 |
288 |
|
Trench P1h |
0 |
6.0 |
5,090 |
159,700 |
99,000 |
718 |
6,030 |
14,600 |
284 |
|
Trench P1h |
0 |
6.0 |
4,950 |
159,850 |
95,300 |
720 |
5,980 |
14,600 |
286 |
|
Trench P1h |
0 |
6.0 |
4,910 |
158,250 |
92,300 |
685 |
5,870 |
14,100 |
285 |
|
Trench P1h |
0 |
6.0 |
4,600 |
148,400 |
86,400 |
726 |
5,480 |
13,700 |
266 |
|
Trench P1h |
0 |
6.0 |
4,620 |
148,250 |
85,800 |
741 |
5,460 |
13,700 |
265 |
|
Trench P1h |
0 |
6.0 |
4,560 |
150,350 |
87,200 |
769 |
5,430 |
13,700 |
265 |
|
Trench P1h |
0 |
6.0 |
4,760 |
151,250 |
90,000 |
746 |
5,670 |
14,000 |
275 |
|
Trench P1h |
0 |
6.0 |
4,900 |
154,400 |
90,600 |
707 |
5,730 |
14,100 |
278 |
|
Trench P1h |
0 |
6.0 |
4,990 |
157,550 |
95,400 |
708 |
5,900 |
14,700 |
281 |
|
Trench P1h |
0 |
6.0 |
5,060 |
160,750 |
95,100 |
683 |
6,060 |
14,600 |
286 |
|
Trench P1h |
0 |
6.0 |
5,180 |
160,900 |
96,100 |
673 |
6,090 |
15,000 |
289 |
|
Trench P1h |
0 |
6.0 |
5,120 |
161,800 |
96,700 |
660 |
6,090 |
14,900 |
290 |
|
Trench P1h |
0 |
6.0 |
5,210 |
163,350 |
96,200 |
690 |
6,210 |
14,900 |
292 |
APPENDIX 3 – LAKE IRWIN TEST PIT LOCATION DATA
|
Hole_ID |
East |
North |
EOH |
Hole_ID |
East |
North |
EOH |
|
|
LITT001 |
399016 |
6880936 |
6.0 |
LITT015 |
399618 |
6873995 |
6.0 |
|
|
LITT002 |
398761 |
6880443 |
6.0 |
LITT016 |
399559 |
6873524 |
6.0 |
|
|
LITT003 |
398522 |
6879966 |
6.0 |
LITT017 |
399618 |
6873995 |
6.0 |
|
|
LITT004 |
398238 |
6879443 |
6.0 |
LITT018 |
390847 |
6885871 |
2.0 |
|
|
LITT005 |
397755 |
6879056 |
6.0 |
LITT019 |
390700 |
6885038 |
2.0 |
|
|
LITT006 |
397755 |
6878524 |
6.0 |
LITT020 |
390002 |
6885153 |
3.0 |
|
|
LITT007 |
397390 |
6877929 |
6.0 |
LITT021 |
389391 |
6885009 |
3.0 |
|
|
LITT008 |
397110 |
6877415 |
6.0 |
LITT022 |
388775 |
6884751 |
3.0 |
|
|
LITT009 |
400186 |
6877199 |
6.0 |
LITT023 |
388409 |
6884440 |
3.0 |
|
|
LITT010 |
400060 |
6876665 |
6.0 |
LITT024 |
364890 |
6904009 |
4.0 |
|
|
LITT011 |
399940 |
6876135 |
6.0 |
LITT025 |
364905 |
6904486 |
4.5 |
|
|
LITT012 |
399701 |
6875633 |
6.0 |
LITT026 |
364879 |
6903453 |
4.0 |
|
|
LITT013 |
399692 |
6875086 |
6.0 |
LITT027 |
364865 |
6903002 |
4.0 |
|
|
LITT014 |
399692 |
6874543 |
6.0 |
APPENDIX 4 – LAKE IRWIN BRINE CHEMISTRY ANALYSIS
|
HOLE ID |
From (m) |
To (m) |
K (mg/L) |
Cl (mg/L) |
Na (mg/L) |
Ca (mg/L) |
Mg (mg/L) |
SO4 (mg/L) |
TDS (g/L) |
|
LITT001 |
0 |
6.0 |
2,410 |
91,150 |
54,700 |
1,240 |
2,230 |
9,930 |
163 |
|
LITT002 |
0 |
6.0 |
2,660 |
99,150 |
59,900 |
1,210 |
2,530 |
10,700 |
177 |
|
LITT003 |
0 |
6.0 |
2,550 |
99,650 |
61,300 |
1,180 |
2,600 |
11,600 |
178 |
|
LITT004 |
0 |
6.0 |
1,810 |
77,350 |
47,100 |
1,280 |
2,160 |
9,360 |
129 |
|
LITT005 |
0 |
6.0 |
1,620 |
69,600 |
42,100 |
1,300 |
2,050 |
8,970 |
125 |
|
LITT006 |
0 |
6.0 |
1,600 |
71,450 |
43,500 |
1,250 |
2,160 |
9,780 |
129 |
|
LITT007 |
0 |
6.0 |
2,360 |
102,750 |
62,800 |
1,050 |
3,020 |
11,700 |
185 |
|
LITT008 |
0 |
6.0 |
1,720 |
72,800 |
46,000 |
1,230 |
2,180 |
10,500 |
133 |
|
LITT009 |
0 |
6.0 |
1,940 |
81,150 |
48,900 |
1,420 |
2,200 |
9,570 |
144 |
|
LITT010 |
0 |
6.0 |
2,190 |
90,250 |
56,200 |
1,320 |
2,500 |
10,200 |
160 |
|
LITT011 |
0 |
6.0 |
2,330 |
92,250 |
56,000 |
1,260 |
2,430 |
9,840 |
166 |
|
LITT012 |
0 |
6.0 |
1,550 |
62,500 |
40,800 |
1,440 |
1,710 |
8,550 |
114 |
|
LITT013 |
0 |
6.0 |
1,700 |
70,200 |
44,700 |
1,410 |
1,870 |
8,640 |
127 |
|
LITT014 |
0 |
6.0 |
2,040 |
87,450 |
54,000 |
1,210 |
2,500 |
10,300 |
158 |
|
LITT015 |
0 |
6.0 |
2,020 |
84,500 |
52,200 |
1,320 |
2,310 |
9,330 |
151 |
|
LITT016 |
0 |
6.0 |
2,840 |
115,900 |
69,500 |
1,160 |
3,080 |
11,100 |
206 |
|
LITT018 |
0 |
2.0 |
1,550 |
78,800 |
49,300 |
1,200 |
2,820 |
10,700 |
144 |
|
LITT019 |
0 |
2.0 |
2,260 |
105,250 |
66,100 |
924 |
3,750 |
13,500 |
191 |
|
LITT020 |
0 |
3.0 |
2,260 |
105,250 |
67,500 |
911 |
3,810 |
13,800 |
191 |
|
LITT021 |
0 |
3.0 |
2,210 |
105,100 |
67,400 |
896 |
3,660 |
14,000 |
191 |
|
LITT022 |
0 |
3.0 |
2,240 |
111,950 |
70,200 |
858 |
3,990 |
14,500 |
196 |
|
LITT023 |
0 |
3.0 |
2,380 |
122,100 |
75,200 |
756 |
4,400 |
15,700 |
221 |
|
LITT024 |
0 |
4.0 |
2,820 |
149,500 |
91,900 |
498 |
6,020 |
21,200 |
273 |
|
LITT025 |
0 |
4.5 |
3,290 |
143,500 |
95,700 |
577 |
5,350 |
20,600 |
263 |
|
LITT026 |
0 |
4.0 |
2,910 |
149,850 |
94,600 |
449 |
6,270 |
23,700 |
278 |
|
LITT027 |
0 |
4.0 |
3,110 |
149,300 |
96,900 |
436 |
5,400 |
25,100 |
280 |
APPENDIX 5 – JORC TABLE ONE
Section 1: Sampling Techniques and Data
|
Criteria |
JORC Code explanation |
Commentary |
|
Sampling techniques |
Nature and quality of sampling (eg cut channels, random chips, or specific specialised industry standard measurement tools appropriate to the minerals under investigation, such as down hole gamma sondes, or handheld XRF instruments, etc). These examples should not be taken as limiting the broad meaning of sampling. Include reference to measures taken to ensure sample representivity and the appropriate calibration of any measurement tools or systems used. Aspects of the determination of mineralisation that are Material to the Public Report. In cases where ‘industry standard’ work has been done this would be relatively simple (eg ‘reverse circulation drilling was used to obtain 1 m samples from which 3 kg was pulverised to produce a 30 g charge for fire assay’). In other cases more explanation may be required, such as where there is coarse gold that has inherent sampling problems. Unusual commodities or mineralisation types (eg submarine nodules) may warrant disclosure of detailed information. |
Lake Wells (drilling) Geological samples were obtained from diamond core drilling. Brine samples were obtained by airlifting PVC cased diamond core holes.
Lake Wells (trench testing) and Lake Irwin Geological samples were obtained from the excavator bucket at regular depth intervals. Brine samples were taken from the discharge of trench dewatering pumps.
|
|
Drilling techniques |
Drill type (eg core, reverse circulation, open-hole hammer, rotary air blast, auger, Bangka, sonic, etc) and details (eg core diameter, triple or standard tube, depth of diamond tails, face-sampling bit or other type, whether core is oriented and if so, by what method, etc). |
Lake Wells (drilling) Diamond core drilling
Lake Wells (trench testing) and Lake Irwin Excavation with a low ground pressure excavator.
|
|
Drill sample recovery |
Method of recording and assessing core and chip sample recoveries and results assessed. Measures taken to maximise sample recovery and ensure representative nature of the samples. Whether a relationship exists between sample recovery and grade and whether sample bias may have occurred due to preferential loss/gain of fine/coarse material. |
Lake Wells (drilling) Geological sample recovery when diamond drilling was high.
Lake Wells (trench testing) and Lake Irwin Not applicable for trenching.
|
|
Logging |
Whether core and chip samples have been geologically and geotechnically logged to a level of detail to support appropriate Mineral Resource estimation, mining studies and metallurgical studies. Whether logging is qualitative or quantitative in nature. Core (or costean, channel, etc) photography. The total length and percentage of the relevant intersections logged. |
Lake Wells (drilling) All drill holes were geologically logged qualitatively by a qualified geologist, noting in particular moisture content of sediments, lithology, colour, induration, grainsize and shape, matrix and structural observations. Flow rate data from airlifting was logged to note water inflow zones.
Lake Wells (trench testing) and Lake Irwin All trenches and test pits were geologically logged qualitatively by a qualified geologist, noting in particular moisture content of sediments, lithology, colour, induration, grainsize and shape, matrix and structural observations. Flow rate data was logged to note water inflow zones.
|
|
Sub-sampling techniques and sample preparation |
If core, whether cut or sawn and whether quarter, half or all core taken. If non-core, whether riffled, tube sampled, rotary split, etc and whether sampled wet or dry. For all sample types, the nature, quality and appropriateness of the sample preparation technique. Quality control procedures adopted for all sub-sampling stages to maximise representivity of samples. Measures taken to ensure that the sampling is representative of the in situ material collected, including for instance results for field duplicate/second-half sampling. Whether sample sizes are appropriate to the grain size of the material being sampled. |
Lake Wells (drilling) Brine samples were obtained during airlifting of cased diamond core holes. Sample bottles are rinsed with brine which is discarded prior to sampling.
Lake Wells (trench testing) and Lake Irwin Brine samples were taken from the discharge of trench dewatering pumps. Sample bottles are rinsed with brine which is discarded prior to sampling. All brine samples taken in the field are split into two sub-samples: primary and duplicate. Reference samples were analysed at a separate laboratory for QA/QC. Representative chip trays and bulk lithological samples are kept for records.
|
|
Quality of assay data and laboratory tests |
The nature, quality and appropriateness of the assaying and laboratory procedures used and whether the technique is considered partial or total. For geophysical tools, spectrometers, handheld XRF instruments, etc, the parameters used in determining the analysis including instrument make and model, reading times, calibrations factors applied and their derivation, etc. Nature of quality control procedures adopted (eg standards, blanks, duplicates, external laboratory checks) and whether acceptable levels of accuracy (ie lack of bias) and precision have been established. |
Primary samples were sent to Bureau Veritas Minerals Laboratory, Perth. Brine samples were analysed using ICP-AES for K, Na, Mg, Ca, with chloride determined by Mohr titration and alkalinity determined volumetrically. Sulphate was calculated from the ICP-AES sulphur analysis.
|
|
Verification of sampling and assaying |
The verification of significant intersections by either independent or alternative company personnel. The use of twinned holes. Documentation of primary data, data entry procedures, data verification, data storage (physical and electronic) protocols. Discuss any adjustment to assay data. |
Data entry is done in the field to minimise transposition errors. Brine assay results are received from the laboratory in digital format, these data sets are subject to the quality control described above. All laboratory results are entered in to the company’s database and validation completed. Independent verification of significant intercepts was not considered warranted given the relatively consistent nature of the brine. |
|
Location of data points |
Accuracy and quality of surveys used to locate drill holes (collar and down-hole surveys), trenches, mine workings and other locations used in Mineral Resource estimation. Specification of the grid system used. Quality and adequacy of topographic control. |
Trench and test pit co-ordinates were captured using hand held GPS. Coordinates were provided in GDA 94_MGA Zone 51. Topographic control is obtained using Geoscience Australia’s 1-second digital elevation product.
|
|
Data spacing and distribution |
Data spacing for reporting of Exploration Results. Whether the data spacing and distribution is sufficient to establish the degree of geological and grade continuity appropriate for the Mineral Resource and Ore Reserve estimation procedure(s) and classifications applied. Whether sample compositing has been applied. |
Lake Wells (drilling) Drill hole spacing is shown on the attached map and varies due to irregular access along the lake edge.
Lake Wells (trench testing) and Lake Irwin Trench hole spacing is shown on the attached maps and varies due to irregular access along the lake edge.
|
|
Orientation of data in relation to geological structure |
Whether the orientation of sampling achieves unbiased sampling of possible structures and the extent to which this is known, considering the deposit type. If the relationship between the drilling orientation and the orientation of key mineralised structures is considered to have introduced a sampling bias, this should be assessed and reported if material. |
Lake Wells (drilling) All drill holes and pits were vertical. Geological structure is considered to be flat lying.
Lake Wells (trench testing) and Lake Irwin Trenches and test pits were vertical. Geological structure is considered to be flat lying.
|
|
Sample security |
The measures taken to ensure sample security. |
All brine samples were marked and kept onsite before transport to the laboratory. All remaining sample and duplicates are stored in the Perth office in climate-controlled conditions. Chain of Custody system is maintained. |
|
Audits or reviews |
The results of any audits or reviews of sampling techniques and data. |
No audits were undertaken. |
Section 2: Reporting of Exploration Results
|
Criteria |
JORC Code explanation |
Commentary |
|
Mineral tenement and land tenure status |
Type, reference name/number, location and ownership including agreements or material issues with third parties such as joint ventures, partnerships, overriding royalties, native title interests, historical sites, wilderness or national park and environmental settings. The security of the tenure held at the time of reporting along with any known impediments to obtaining a licence to operate in the area.
|
Lake Wells Tenements excavated were granted exploration licences 38/2710, 38/2821, 38/2824, 38/3055, 38/3056 and 38/3057 in Western Australia.
Lake Irwin Tenements sampled 37/1233, 38/3087 and 39/1892 in Western Australia. Exploration Licenses are held by Piper Preston Pty Ltd (fully owned subsidiary of ASLP). |
|
Exploration done by other parties |
Acknowledgment and appraisal of exploration by other parties. |
Details are presented in the report.
|
|
Geology |
Deposit type, geological setting and style of mineralisation. |
Salt Lake Brine Deposit
|
|
Drill hole Information |
A summary of all information material to the understanding of the exploration results including a tabulation of the following information for all Material drill holes: o easting and northing of the drill hole collar o elevation or RL (Reduced Level – elevation above sea level in metres) of the drill hole collar o dip and azimuth of the hole o down hole length and interception depth o hole length. If the exclusion of this information is justified on the basis that the information is not Material and this exclusion does not detract from the understanding of the report, the Competent Person should clearly explain why this is the case. |
Details are presented in the report.
|
|
Data aggregation methods |
In reporting Exploration Results, weighting averaging techniques, maximum and/or minimum grade truncations (eg cutting of high grades) and cut-off grades are usually Material and should be stated. Where aggregate intercepts incorporate short lengths of high grade results and longer lengths of low grade results, the procedure used for such aggregation should be stated and some typical examples of such aggregations should be shown in detail. The assumptions used for any reporting of metal equivalent values should be clearly stated. |
Details are presented in the report.
|
|
Relationship between mineralisation widths and intercept lengths |
These relationships are particularly important in the reporting of Exploration Results. If the geometry of the mineralisation with respect to the drill hole angle is known, its nature should be reported. If it is not known and only the down hole lengths are reported, there should be a clear statement to this effect (eg ‘down hole length, true width not known’). |
Lake Wells (drilling) The unit is flat lying and drill holes are vertical hence the intersected downhole depth is equivalent to the inferred thickness of mineralisation
Lake Wells (trench testing) and Lake Irwin The unit is flat lying and trenches and pits are vertical hence the intersected downhole depth is equivalent to the inferred thickness of mineralisation.
|
|
Diagrams |
Appropriate maps and sections (with scales) and tabulations of intercepts should be included for any significant discovery being reported These should include, but not be limited to a plan view of drill hole collar locations and appropriate sectional views. |
Addressed in the announcement. |
|
Balanced reporting |
Where comprehensive reporting of all Exploration Results is not practicable, representative reporting of both low and high grades and/or widths should be practiced to avoid misleading reporting of Exploration Results. |
All results have been included. |
|
Other substantive exploration data |
Other exploration data, if meaningful and material, should be reported including (but not limited to): geological observations; geophysical survey results; geochemical survey results; bulk samples – size and method of treatment; metallurgical test results; bulk density, groundwater, geotechnical and rock characteristics; potential deleterious or contaminating substances. |
Gravity survey was completed by Atlas Geophysics using a Hi Target V100 GNSS receiver for accurate positioning and CG-5 Digital Automated Gravity Meter. Gravity data was gained using the contractors rapid acquisition, high accuracy UTV borne techniques. The company’s own in-house reduction and QA software was used to reduce the data on a daily basis to ensure quality and integrity. All gravity meters were calibrated pre and post survey and meter drift rates were monitored daily. 3 to 5 % of the stations are repeated for quality control. Western Geophysics were engaged to manage and process the gravity survey. Processing the survey involved reducing the gravity data and integrating to the regional data to a residual anomaly which shows there is a semi-continuous distinct residual gravity low of negative 2 to 2.5 milligals present along eastern to central areas to the entire tenement area. |
|
Further work |
The nature and scale of planned further work (eg tests for lateral extensions or depth extensions or large-scale step-out drilling). Diagrams clearly highlighting the areas of possible extensions, including the main geological interpretations and future drilling areas, provided this information is not commercially sensitive. |
Further trench testing and numerical hydrogeological modelling to be completed that incorporates the results of the test pumping. The model will be the basis of the annual brine abstraction rate and mine life.
|
For further information please visit www.saltlakepotash.com.au or contact:
|
Sam Cordin |
Salt Lake Potash Limited |
Tel: +61 8 9322 6322 |
|
Colin Aaronson/Richard Tonthat |
Grant Thornton UK LLP (Nominated Adviser) |
Tel: +44 (0) 207 383 5100 |
|
Nick Tulloch/Beth McKiernan |
Cenkos Securities plc (Joint broker) |
Tel: +44 (0) 131 220 6939 |
|
Jerry Keen/Toby Gibbs |
Shore Capital (Joint broker) |
Tel: +44 (0 207 468 7967 |
[1] WMC Resource Limited report by AGC Woodward Pty Ltd, 1992, Mt Keith Project, Process Water Supply Study, Lake Way Area, Volume I and II, Report