GREENWING RESOURCES LTD — Capital/Financing Update 2018

Sep 10, 2018

ASX Announcement 11 September 2018

Bass Metals Ltd delivers outstanding high grade channel sample intersection of 31 metres at 3.72% Lithium Oxide (Li2O) at its 100% owned Millie’s Reward Project.

HIGHLIGHTS

• Channel sampling at the Millie’s West prospect has returned a weighted average intersection of 3.72% Lithium Oxide (Li2O) over 31m, with a maximum 1m result yielding 6.61% Li2O.

• New Rock-chip samples across five prospects within the Millie’s Reward project yielded Li2O values up to 7.15%, 5.96%, 4.09%, 5.71% and 6.22%.

• Orientation soil samples at Millie’s West & Ilapa prospects yielded Lithium values up to 787ppm over 55m and 66ppm over 15m, respectively.

• Bass to commence drilling program at Millie’s West in the coming weeks.

Bass Metals Limited (ASX: “BSM”) (the “Company”) is pleased to announce additional results further highlighting the potential for delineating a high grade lithium-in-spodumene resource at the Millie’s Reward Project, located in central Madagascar.

Outstanding channel sample results have returned 31 metres of continuous mineralization at a grade of 3.72% Li2O from a sampling program focused on the Ampatsikahitra prospect (Millie’s West). The program included orientation soil sampling, with additional rock chip sampling which yielded further high grade results.

The channel samples at Millie’s West, were taken at 1 metre continuous intervals over 31 meters, in an area previously worked by local prospectors for gem quality Spodumene (lithium). The sampling commenced from just below surface and followed shallow dipping pegmatite mineralization to depth, with sampling ending in mineralization, indicating the Millie’s West Pegmatite continues and is open in all directions. All samples have been independently tested and verified by an accredited laboratory and are part of a Phase 1 exploration program to establish high priority drill targets.

The Phase 1 program continued systematic exploration by various sampling techniques, detailed mapping of historical workings and geological observations across a number of other prospects within the tenement package.

KEY RESULTS FROM MILLIE’S WEST:

• Channel sampling of previous workings along the schist / pegmatite contact and diagonally in depth into the pegmatite, yielded a weighted average of 3.72% Li2O over 31 metres including a maximum value of 6.61% Li2O, which exceed current chemical grade concentrate specifications.

• Additional Rock-chip sampling from artisanal pits and shafts at Millie’s West yielded values up to 7.15% Li2O; and

• Orientation soil samples at Millie’s West, over 330m, yielded lithium values up to 787ppm.

Based on these highly encouraging preliminary results, Millie’s West will enter Phase 2 of a diamond drilling program of 300 to 600m, which is planned to commence this month. The Phase 2 drilling will focus on the pegmatite geometry, structure and mineralisation for the Millie’s West prospect. In preparation for the drilling program, road access was installed in August via road repairs, followed by installation of a new road to the prospect.

A soil geochemical sampling program has already commenced with 418 samples in a 40m x 20m spacing at Millie’s West, which aims to identify lithium soil anomalies in order to define the total width and strike length of the prospect’s mineralization footprint, with a view of expanding drilling operations post the results of initial drilling.

KEY RESULTS FROM OTHER PROSPECTS:

Ilapa

• Collected 26 composite rock-chip samples from lithium-bearing pegmatite outcrops, returning up to 5.96% Li2O with pathfinder trace elements; 5590 ppm Cs, 283 ppm Tl, 349 ppm Nb, >10,000 ppm Rb, and 1510 ppm Be; and

• Collected 28 soil samples over a 295m orientation line, which yielded lithium values up to 66 ppm over 15 metres, identifying a potential lithium zone coinciding with artisanal pegmatite workings.

Tsarafara

• Collected 2 composite rock-chip samples over lithium-bearing pegmatites outcrops, returning up to 4.09% Li2O with pathfinder trace elements; 3700 ppm Cs, 137 ppm Nb and 5320 ppm Rb.

Tsararano

• Collected 5 composite rock-chip samples over lithium-bearing pegmatite outcrops, returning up to 5.71% Li2O with pathfinder trace elements; 5540 ppm Cs, 372 ppm Ta, 287 ppm Nb, 5090 ppm Rb and 113 ppm Be.

Vietnam

• Collected 2 composite rock-chip samples over lithium-bearing pegmatite outcrops, returning up to 6.22% Li2O with pathfinder trace elements; 824 ppm Cs, 1260 ppm Rb and 900 ppm Be.

MILLIE’S REWARD NORTHERN PROSPECTS MAP

==> picture [369 x 521] intentionally omitted <==

Figure 1: Ampatsikahitra = Millie’s West.

SUMMARY OF RESULTS

A summary of maximum values for lithium and pathfinder trace elements.

PROSPECT SAMPLE TYPE NUMBER OF SAMPLES LI PPM LI2O % CS PPM TA PPM NB PPM RB PPM BE PPM	PROSPECT SAMPLE TYPE NUMBER OF SAMPLES LI PPM LI2O % CS PPM TA PPM NB PPM RB PPM BE PPM
MILLIE’S WEST	Channel 36 6.61 1,060 414 678 2,220 2,320
	Rock 26 7.15 5,480 234 392 9,530 175
	Soil 34 787 51 178 23
ILAPA	Rock 26 5.96 5,590 273 349 >10,000 1,510
	Soil 28 16
TSARAFARA	Rock 2 4.09 3,700 137 5,320
TSARARANO	Rock 5 5.71 5,540 372 287 5,090 113
VIETNAM	Rock 2 6.22 824 1260 900

This data provides strong reinforcement of Bass’ view (ASX announcement 16[th] April 2018) that the Millie’s Reward Project warrants a comprehensive drill program to follow up the outstanding surface signatures encountered to date, with these results providing the most compelling data to date to support the Company’s aims to delineate a potential resource of significance at Millie’s.

In addition to the comprehensive exploration works to date, Bass has begun its community consultation program within the region and are exceptionally happy with the reception received by the region’s communities. Bass looks forward to keeping the market appraised of its progress at Millie’s as it advances toward its maiden drill program.

MR TIM MCMANUS CEO:

“The team is exceptionally pleased at this glimpse into what Millie’s could ultimately be. We have yet to see early results from any other lithium discovery that compare to the surface expression being encountered at Millie’s and the potential we see to take the project forward rapidly.

It is very exciting to have a project such as Millie’s in our portfolio while at the same time our Graphmada Graphite Mine has reached nameplate capacity with first sales completed. We are now looking forward to achieving our primary focus of positive cash flow from operations while expanding our resource inventory in both graphite and lithium. This is being done in parallel with our long stated strategy of expanding production at Graphmada and developing downstream Expandable Graphite production and technologies.

Our ultimate aim is to create an industrial minerals company of significance and generate substantial long term value for our shareholders.”

MR PETER WRIGHT EXECUTIVE DIRECTOR:

“These results are outstanding and highlight the significant potential of the Millie’s Reward Project and we are looking forward to the commencement of drilling in the next few weeks.

As Bass looks to finalise its Stage 1 objectives through achieving positive cash flow from operations, while retaining a prudent cash balance, the Company will pursue Stage 2 and 3, free of debt and with 100% ownership of its assets to form a strong and robust platform both operationally and financial.”

FOR MORE INFORMATION PLEASE CONTACT:

Tim McManus Peter Wright Chief Executive Officer Executive Director Email: admin@bassmetals.com.au Email: admin@bassmetals.com.au Phone: 07 3203 5894 Phone: 07 3203 5894

Web: www.bassmetals.com.au Twitter: @bassmetals

ABOUT BASS METALS

Bass Metals Ltd. is a producer of industrial mineral concentrates post the successful Stage 1 commercial ramp up of production at its 100% owned and debt free Graphmada Large Flake Graphite Mine.

The Graphmada Mine is located in eastern Madagascar, a democratic island country in the Indian Ocean, off the coast of Southeast Africa, which is governed under a French legal system with a low Corporate Tax rate of 20% and a low 2% Mining Royalty.

The country has produced benchmark quality graphite for over 100 years due to the high proportion of high purity, large flake, premium quality graphite in soft, easily minable, saprolitic ore. Therefore, deposits, like those at Graphmada, have low operating costs and extremely low capital costs when compared to other African or Western deposits. The welldeveloped export infrastructure is also a significant aspect that makes working in Madagascar attractive.

The Graphmada Mine has 40-year mining permits and 20-year landholder agreements in place, with four premium quality, large flake, graphite deposits. With all associated mining infrastructure and logistics in place, the mine currently produces and sells a range of graphite concentrates into multiple market segments, to customers in Europe under an offtake agreement, and on order to customers in India, China and the United States.

Producing premium large flake concentrates at a time of rising prices, Bass as one of only two ASX listed producers, and one of only four publicly listed graphite producers globally, is working to expand production from 6,000 tonnes per annum (tpa) to beyond 20,000 tpa (Stage 2) and in addition, pursue a strategy to develop downstream Expandable Graphite production and technologies (Stage 3) for which our graphite concentrates are highly suitable.

With an established and growing production platform, complimented with the Company’s prudent capital management, strong cash position, zero debt and sustainable cash flow, Bass is on a robust operational and financial platform to pursue and realise the considerable potential of exploring Madagascar and developing the Company’s assets, such as the 100% owned highly prospective Millie’s Reward lithium project which is being fast tracked via an extensive drilling program.

DISCLAIMER, STATEMENTS & IMPORTANT INFORMATION

Disclaimer

This document has been prepared by Bass Metals Limited (the “Company”). It should not be considered as an invitation or offer to subscribe for or purchase any securities in the Company or as an inducement to make an invitation or offer with respect to those securities. No agreement to subscribe for securities in the Company will be entered into on the basis of this document.

This document is provided on the basis that neither the Company nor its officers, shareholders, related bodies corporate, partners, affiliates, employees, representatives and advisers make any representation or warranty (express or implied) as to the accuracy, reliability, relevance or completeness of the material contained in the document and nothing contained in the document is, or may be relied upon as a promise, representation or warranty, whether as to the past or the future. The Company hereby excludes all warranties that can be excluded by law.

Forward Looking Statements

This announcement contains certain ‘forward-looking statements’ within the meaning of the securities laws of applicable jurisdictions. Forward-looking statements can generally be identified by the use of forward-looking words such as ‘may,’ ‘should,’ ‘expect,’ ‘anticipate,’ ‘estimate,’ ‘scheduled’ or ‘continue’ or the negative version of them or comparable terminology.

Any forecasts or other forward-looking statements contained in this announcement are subject to known and unknown risks and uncertainties and may involve significant elements of subjective judgment and assumptions as to future events which may or may not be correct. There are usually differences between forecast and actual results because events and actual circumstances frequently do not occur as forecast and these differences may be material.

Bass Metals does not give any representation, assurance or guarantee that the occurrence of the events expressed or implied in any forward-looking statements in this announcement will actually occur and you are cautioned not to place undue reliance on forward-looking statements. The information in this document does not take into account the objectives, financial situation or particular needs of any person. Nothing contained in this document constitutes investment, legal, tax or other advice.

Important information

This announcement does not constitute an offer to sell, or a solicitation of an offer to buy, securities in the United States, or in any other jurisdiction in which such an offer would be illegal. The securities referred to in this document have not been and will not be registered under the United States Securities Act of 1933 (the ‘US Securities Act’), or under the securities laws of any state or other jurisdiction of the United States and may not be offered or sold, directly or indirectly, within the United States, unless the securities have been registered under the US Securities Act or an exemption from the registration requirements of the US Securities Act is available.

This document may not be distributed or released in the United States.

Competent Person Statement

The information in this document that relates to Exploration Results is based on information compiled by Tim McManus, a Competent Person who is a member of the Australasian Institute of Mining and Metallurgy and a fulltime employee of the Company.

Tim McManus has sufficient experience that is relevant to the style of mineralization and type of deposit under consideration and to the activity being undertaken 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.

Tim McManus consents to the inclusion of the information in this document in the form and context in which it appears.

APPENDIX 1: CHANNEL SAMPLE RESULTS

Prospect	Collar ID	Utm **38sX **	Utm **38sY **	Sample ID	From Metre	To Metre	Lithology	Li ppm	Li2O %	Be **ppm **	Cs **ppm **	Nb **ppm **	Ta **ppm **
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0151	11	12	Pegmatite	381	0.08	223	582	150	41
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0153	12	13	Pegmatite	347	0.07	52	215	210	27
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0154	13	14	Pegmatite	471	0.10	449	346	275	43
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0155	14	15	Pegmatite	401	0.09	59	82	358	53
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0156	15	16	Pegmatite	348	0.07	72	58	227	37
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0157	16	17	Lithium- bearing pegmatite	14300	3.08	407	138	163	53
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0158	17	18	Lithium- bearing pegmatite	15300	3.29	230	124	133	29
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0159	18	19	Lithium- bearing pegmatite	11900	2.56	20	105	195	96
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0162	19	20	Lithium- bearing pegmatite	10900	2.35	136	130	172	38
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0163	20	21	Lithium- bearing pegmatite	7280	1.57	2320	307	143	35
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0164	21	22	Lithium- bearing pegmatite	22400	4.82	112	45	45	30
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0166	22	23	Lithium- bearing pegmatite	21900	4.72	44	110	21	35
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0168	23	24	Lithium- bearing pegmatite	11100	2.39	101	108	43	15
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0170	24	25	Lithium- bearing pegmatite	345	0.07	739	334	189	44
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0172	25	26	Lithium- bearing pegmatite	8800	1.89	75	486	145	35
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0174	26	27	Lithium- bearing pegmatite	18800	4.05	3	168	678	414
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0176	27	28	Lithium- bearing pegmatite	12500	2.69	206	237	78	29
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0178	28	29	Lithium- bearing pegmatite	12600	2.71	3	239	88	137
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0181	29	30	Lithium- bearing pegmatite	18500	3.98	5	169	65	34
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0182	30	31	Lithium- bearing pegmatite	19300	4.16	82	93	111	176
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0183	31	32	Lithium- bearing pegmatite	14800	3.19	88	119	48	47
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0184	32	33	Lithium- bearing pegmatite	21400	4.61	3	136	14	39
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0185	33	34	Lithium- bearing pegmatite	16600	3.57	183	108	66	49
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0186	34	35	Lithium- bearing pegmatite	13500	2.91	20	77	79	117

Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0187	35	36	Lithium- bearing pegmatite	23700	5.10	3	57	55	170
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0188	36	37	Lithium- bearing pegmatite	20100	4.33	187	145	94	170
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0189	37	38	Lithium- bearing pegmatite	13100	2.82	291	177	184	117
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0191	38	39	Lithium- bearing pegmatite	19600	4.22	10	154	38	84
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0192	39	40	Lithium- bearing pegmatite	13100	2.82	255	412	212	109
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0193	40	41	Lithium- bearing pegmatite	20500	4.41	307	359	16	21
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0194	41	42	Lithium- bearing pegmatite	28600	6.16	5	115	44	87
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0195	42	43	Lithium- bearing pegmatite	19200	4.13	921	1060	296	376
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0196	43	44	Lithium- bearing pegmatite	19300	4.16	41	120	114	76
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0197	44	45	Lithium- bearing pegmatite	28800	6.20	24	78	38	77
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0198	45	46	Lithium- bearing pegmatite	26600	5.73	13	64	28	83
Ampatsi kahitra	BSMUG00 1	703,0 27	7,780 ,834	P0199	46	47	Lithium- bearing pegmatite	30700	6.61	52	76	8	20

APPENDIX 2: SOIL SAMPLE RESULTS

Prospect	Collar ID	Utm 38sX	Utm 38sY	Sample ID	Sieve Fraction	Li (ppm)	Be (ppm)	Cs (ppm)	Nb (ppm)	Ta (ppm)
Ampatsikahitra	LineB1_ 01	702,8 81	7,780 ,850	P0207	+2mm	7	0.5	6.4	1.4	0.0
	LineB1_ 01	702,8 81	7,780 ,850	P0208	-2mm to +180µm	6	0.4	5.8	1.4	0.1
	LineB1_ 01	702,8 81	7,780 ,850	P0209	-180µm to +75µm	11	0.6	9.1	2.0	0.1
	LineB1_ 01	702,8 81	7,780 ,850	P0210	-75µm	8	0.7	10.4	2.5	0.1
	LineB1_ 02	702,9 01	7,780 ,847	P0211	+2mm	6	0.4	5.0	4.3	0.1
	LineB1_ 02	702,9 01	7,780 ,847	P0212	-2mm to +180µm	6	0.4	4.6	4.2	0.1
	LineB1_ 02	702,9 01	7,780 ,847	P0213	-180µm to +75µm	5	0.5	6.5	6.4	0.0
	LineB1_ 02	702,9 01	7,780 ,847	P0214	-75µm	7	0.7	8.4	7.6	0.1
	LineB1_ 03	702,9 21	7,780 ,844	P0215	+2mm	7	0.7	5.9	2.3	0.0
	LineB1_ 03	702,9 21	7,780 ,844	P0216	-2mm to +180µm	6	0.6	5.1	2.1	0.1
	LineB1_ 03	702,9 21	7,780 ,844	P0217	-180µm to +75µm	7	0.8	6.8	2.3	0.0
	LineB1_ 03	702,9 21	7,780 ,844	P0218	-75µm	10	1.1	9.3	3.7	0.0
	LineB1_ 04	702,9 41	7,780 ,841	P0219	+2mm	7	0.6	5.5	2.1	0.0

											13 13 0.0 0.0 0.0 0.0 0.0 0.1 0.0 0.1 0.1 0.1 0.0 0.0 0.0 0.0 0.0 0.0 0.2 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1
		LineB1_ 04	702,9 41	7,780 ,841	P0221	-2mm to +180µm	6	0.5	4.9	2.1	0.0
		LineB1_ 04	702,9 41	7,780 ,841	P0222	-180µm to +75µm	7	0.7	6.6	3.1	0.0
		LineB1_ 04	702,9 41	7,780 ,841	P0223	-75µm	7	0.8	7.4	3.6	0.0
		LineB1_ 05	702,9 61	7,780 ,838	P0224	+2mm	11	0.9	6.3	2.7	0.0
		LineB1_ 05	702,9 61	7,780 ,838	P0225	-2mm to +180µm	10	0.7	5.2	2.1	0.0
		LineB1_ 05	702,9 61	7,780 ,838	P0226	-180µm to +75µm	10	0.8	6.7	2.9	0.1
		LineB1_ 05	702,9 61	7,780 ,838	P0227	-75µm	14	0.9	7.7	3.2	0.0
		LineB1_ 06	702,9 71	7,780 ,836	P0228	+2mm	8	0.9	4.1	1.3	0.1
		LineB1_ 06	702,9 71	7,780 ,836	P0229	-2mm to +180µm	6	0.8	3.5	1.5	0.1
		LineB1_ 06	702,9 71	7,780 ,836	P0230	-180µm to +75µm	7	1.1	5.1	1.7	0.1
		LineB1_ 06	702,9 71	7,780 ,836	P0231	-75µm	9	1.2	6.0	1.6	0.0
		LineB1_ 07	702,9 81	7,780 ,835	P0232	+2mm	28	1.5	2.0	0.5	0.0
		LineB1_ 07	702,9 81	7,780 ,835	P0233	-2mm to +180µm	30	1.5	2.3	0.4	0.0
		LineB1_ 07	702,9 81	7,780 ,835	P0234	-180µm to +75µm	18	1.4	2.4	0.4	0.0
		LineB1_ 07	702,9 81	7,780 ,835	P0235	-75µm	18	1.6	2.7	0.4	0.0
		LineB1_ 08	702,9 91	7,780 ,833	P0236	+2mm	75	4.0	0.7	0.2	0.0
		LineB1_ 08	702,9 91	7,780 ,833	P0237	-2mm to +180µm	90	5.1	0.8	0.8	0.2
		LineB1_ 08	702,9 91	7780 833.4 7	P0238	-180µm to +75µm	46	5.5	0.8	0.5	0.1
		LineB1_ 08	702,9 91	7780 833.4 7	P0239	-75µm	35	7.7	0.8	0.4	0.1
		LineB1_ 09	703,0 01	7780 832	P0241	+2mm	117	23.2	1.1	0.5	0.1
		LineB1_ 09	703,0 01	7780 832	P0242	-2mm to +180µm	98	17.1	1.0	0.5	0.1
		LineB1_ 09	703,0 01	7780 832	P0243	-180µm to +75µm	101	10.9	0.9	0.4	0.1
		LineB1_ 09	703,0 01	7780 832	P0244	-75µm	95	19.8	1.4	0.4	0.1
		LineB1_ 10	703,0 06	7780 831.2 6	P0245	+2mm	273	3.5	13.7	0.3	0.1
		LineB1_ 10	703,0 06	7780 831.2 6	P0246	-2mm to +180µm	458	4.5	20.4	0.4	0.1
		LineB1_ 10	703,0 06	7780 831.2 6	P0247	-180µm to +75µm	312	3.7	12.5	0.3	0.1
		LineB1_ 10	703,0 06	7,780 ,831	P0248	-75µm	506	3.6	23.8	0.3	0.1
		LineB1_ 11	703,0 11	7,780 ,831	P0249	+2mm	128	7.3	8.5	0.3	0.1
		LineB1_ 11	703,0 11	7,780 ,831	P0251	-2mm to +180µm	595	6.6	29.7	0.3	0.1
		LineB1_ 11	703,0 11	7,780 ,831	P0252	-180µm to +75µm	635	4.7	31.2	0.7	0.1
		LineB1_ 11	703,0 11	7,780 ,831	P0253	-75µm	556	8.6	29.3	0.3	0.1
		LineB1_ 12	703,0 16	7,780 ,830	P0254	+2mm	249	10.8	5.2	0.2	0.1
		LineB1_ 12	703,0 16	7,780 ,830	P0255	-2mm to +180µm	252	12.6	5.8	0.2	0.1
		LineB1_ 12	703,0 16	7,780 ,830	P0256	-180µm to +75µm	285	7.5	5.2	0.2	0.1

											14 14 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.3 0.3 0.3 0.3 0.1 0.3 0.2 0.1 0.1 0.1 0.1 0.1 0.1 0.1
		LineB1_ 12	703,0 16	7,780 ,830	P0257	-75µm	287	7.4	5.2	0.2	0.1
		LineB1_ 13	703,0 21	7,780 ,829	P0258	+2mm	226	3.2	12.3	0.2	0.1
		LineB1_ 13	703,0 21	7,780 ,829	P0259	-2mm to +180µm	210	3.5	15.0	0.2	0.1
		LineB1_ 13	703,0 21	7,780 ,829	P0261	-180µm to +75µm	258	2.6	10.4	0.2	0.1
		LineB1_ 13	703,0 21	7,780 ,829	P0262	-75µm	192	2.2	8.2	0.6	0.1
		LineB1_ 14	703,0 26	7,780 ,828	P0263	+2mm	655	6.8	42.1	0.8	0.1
		LineB1_ 14	703,0 26	7,780 ,828	P0264	-2mm to +180µm	787	7.8	51.4	0.2	0.1
		LineB1_ 14	703,0 26	7,780 ,828	P0265	-180µm to +75µm	630	5.5	40.2	0.2	0.1
		LineB1_ 14	703,0 26	7,780 ,828	P0266	-75µm	401	6.9	27.3	0.2	0.1
		LineB1_ 15	703,0 31	7,780 ,828	P0267	+2mm	98	2.9	4.1	0.1	0.1
		LineB1_ 15	703,0 31	7,780 ,828	P0268	-2mm to +180µm	87	3.2	3.6	0.2	0.1
		LineB1_ 15	703,0 31	7,780 ,828	P0269	-180µm to +75µm	92	3.2	3.6	0.2	0.1
		LineB1_ 15	703,0 31	7,780 ,828	P0270	-75µm	83	3.0	2.8	0.1	0.1
		LineB1_ 16	703,0 36	7,780 ,827	P0271	+2mm	78	2.8	7.2	0.3	0.1
		LineB1_ 16	703,0 36	7,780 ,827	P0272	-2mm to +180µm	76	2.9	6.7	0.2	0.1
		LineB1_ 16	703,0 36	7,780 ,827	P0273	-180µm to +75µm	83	3.3	8.3	0.2	0.1
		LineB1_ 16	703,0 36	7,780 ,827	P0274	-75µm	71	2.7	6.0	0.2	0.1
		LineB1_ 17	703,0 41	7,780 ,826	P0275	+2mm	288	1.5	1.4	0.2	0.1
		LineB1_ 17	703,0 41	7,780 ,826	P0276	-2mm to +180µm	349	1.4	1.6	0.2	0.1
		LineB1_ 17	703,0 41	7,780 ,826	P0277	-180µm to +75µm	360	1.3	1.4	0.1	0.1
		LineB1_ 17	703,0 41	7,780 ,826	P0278	-75µm	424	1.7	2.1	0.1	0.1
		LineB1_ 18	703,0 46	7,780 ,825	P0279	+2mm	78	2.2	5.7	0.2	0.1
		LineB1_ 18	703,0 46	7,780 ,825	P0281	-2mm to +180µm	97	2.3	5.8	0.2	0.3
		LineB1_ 18	703,0 46	7,780 ,825	P0282	-180µm to +75µm	118	2.3	6.0	0.2	0.3
		LineB1_ 18	703,0 46	7,780 ,825	P0283	-75µm	138	2.9	7.0	0.1	0.3
		LineB1_ 19	703,0 51	7,780 ,825	P0284	+2mm	103	2.1	7.1	0.1	0.3
		LineB1_ 19	703,0 51	7,780 ,825	P0285	-2mm to +180µm	96	1.7	6.4	0.1	0.1
		LineB1_ 19	703,0 51	7,780 ,825	P0286	-180µm to +75µm	113	2.2	6.8	0.1	0.3
		LineB1_ 19	703,0 51	7,780 ,825	P0287	-75µm	107	2.4	6.9	0.7	0.2
		LineB1_ 20	703,0 56	7,780 ,824	P0288	+2mm	85	1.9	6.3	0.5	0.1
		LineB1_ 20	703,0 56	7,780 ,824	P0289	-2mm to +180µm	103	1.9	6.5	0.5	0.1
		LineB1_ 20	703,0 56	7,780 ,824	P0291	-180µm to +75µm	136	2.2	6.7	0.4	0.1
		LineB1_ 20	703,0 56	7,780 ,824	P0292	-75µm	126	1.6	5.3	0.2	0.1
		LineB1_ 21	703,0 61	7,780 ,823	P0293	+2mm	53	0.9	0.7	0.3	0.1
		LineB1_ 21	703,0 61	7,780 ,823	P0294	-2mm to +180µm	69	1.2	0.6	0.2	0.1
		LineB1_ 21	703,0 61	7,780 ,823	P0295	-180µm to +75µm	58	1.3	0.5	0.3	0.1

											15 15 0.1 0.1 0.3 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1
		LineB1_ 21	703,0 61	7,780 ,823	P0296	-75µm	52	1.3	0.9	0.4	0.1
		LineB1_ 22	703,0 66	7,780 ,822	P0297	+2mm	87	1.2	0.7	0.3	0.1
		LineB1_ 22	703,0 66	7,780 ,822	P0298	-2mm to +180µm	89	1.2	0.6	0.2	0.3
		LineB1_ 22	703,0 66	7,780 ,822	P0299	-180µm to +75µm	67	1.1	0.5	0.2	0.1
		LineB1_ 22	703,0 66	7,780 ,822	P0301	-75µm	41	0.8	0.6	0.3	0.1
		LineB1_ 23	703,0 70	7,780 ,822	P0302	+2mm	43	0.4	1.6	0.3	0.1
		LineB1_ 23	703,0 70	7,780 ,822	P0303	-2mm to +180µm	55	0.7	1.2	0.3	0.1
		LineB1_ 23	703,0 70	7,780 ,822	P0304	-180µm to +75µm	49	0.5	0.9	0.3	0.1
		LineB1_ 23	703,0 70	7,780 ,822	P0305	-75µm	50	0.5	1.3	0.3	0.1
		LineB1_ 24	703,0 75	7,780 ,821	P0306	+2mm	89	3.6	0.9	0.4	0.1
		LineB1_ 24	703,0 75	7,780 ,821	P0307	-2mm to +180µm	102	3.7	0.9	0.4	0.1
		LineB1_ 24	703,0 75	7,780 ,821	P0308	-180µm to +75µm	113	4.0	0.6	0.4	0.1
		LineB1_ 24	703,0 75	7,780 ,821	P0309	-75µm	113	4.0	0.8	0.3	0.1
		LineB1_ 24	703,0 75	7,780 ,821	P0310	+2mm	25	1.5	0.8	0.4	0.1
		LineB1_ 24	703,0 75	7,780 ,821	P0311	-2mm to +180µm	23	1.1	0.8	0.8	0.1
		LineB1_ 24	703,0 75	7,780 ,821	P0312	-180µm to +75µm	35	1.8	1.0	0.3	0.1
		LineB1_ 24	703,0 75	7,780 ,821	P0313	-75µm	36	2.2	1.2	0.3	0.1
		LineB1_ 24	703,0 75	7,780 ,821	P0314	+2mm	103	5.6	0.6	0.3	0.1
		LineB1_ 24	703,0 75	7,780 ,821	P0315	-2mm to +180µm	95	5.8	0.5	0.2	0.1
		LineB1_ 24	703,0 75	7,780 ,821	P0316	-180µm to +75µm	81	4.7	0.3	0.2	0.1
		LineB1_ 24	703,0 75	7,780 ,821	P0317	-75µm	75	3.8	0.4	0.2	0.1
		LineB1_ 25	703,0 80	7,780 ,820	P0318	+2mm	60	1.9	3.8	0.6	0.1
		LineB1_ 25	703,0 80	7,780 ,820	P0319	-2mm to +180µm	52	1.9	3.8	0.6	0.1
		LineB1_ 25	703,0 80	7,780 ,820	P0321	-180µm to +75µm	60	1.9	5.3	0.7	0.1
		LineB1_ 25	703,0 80	7,780 ,820	P0322	-75µm	75	2.6	4.9	0.6	0.1
		LineB1_ 26	703,0 85	7,780 ,819	P0323	+2mm	159	4.7	3.4	0.5	0.1
		LineB1_ 26	703,0 85	7,780 ,819	P0324	-2mm to +180µm	157	5.1	3.5	0.6	0.1
		LineB1_ 26	703,0 85	7,780 ,819	P0325	-180µm to +75µm	184	5.0	3.0	0.5	0.1
		LineB1_ 26	703,0 85	7,780 ,819	P0326	-75µm	172	4.9	2.7	0.4	0.1
		LineB1_ 27	703,0 95	7,780 ,818	P0327	+2mm	31	2.1	2.5	0.7	0.1
		LineB1_ 27	703,0 95	7,780 ,818	P0328	-2mm to +180µm	22	1.5	1.8	0.6	0.1
		LineB1_ 27	703,0 95	7,780 ,818	P0329	-180µm to +75µm	34	2.2	3.4	0.7	0.1
		LineB1_ 27	703,0 95	7,780 ,818	P0330	-75µm	31	2.2	2.8	0.7	0.1
		LineB1_ 28	703,1 05	7,780 ,816	P0331	+2mm	33	2.8	1.6	0.6	0.1
		LineB1_ 28	703,1 05	7,780 ,816	P0332	-2mm to +180µm	40	3.5	2.0	0.7	0.1
		LineB1_ 28	703,1 05	7,780 ,816	P0333	-180µm to +75µm	34	3.0	1.8	1.0	0.1

											16 16 0.1 0.1 0.1 0.2 0.2 0.2 0.2 0.2 0.1 0.1 0.2 0.1 0.1 0.1 0.2 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.2 0.2 0.2 0.2 0.3 0.1 0.2 0.1 0.1 0.2 0.2
		LineB1_ 28	703,1 05	7,780 ,816	P0334	-75µm	33	3.4	1.8	1.2	0.1
		LineB1_ 29	703,1 15	7,780 ,815	P0335	+2mm	32	2.9	1.3	1.1	0.1
		LineB1_ 29	703,1 15	7,780 ,815	P0336	-2mm to +180µm	29	2.5	1.3	0.8	0.1
		LineB1_ 29	703,1 15	7,780 ,815	P0337	-180µm to +75µm	33	3.3	1.7	1.0	0.2
		LineB1_ 29	703,1 15	7,780 ,815	P0338	-75µm	39	3.7	1.8	0.7	0.2
		LineB1_ 30	703,1 25	7,780 ,813	P0339	+2mm	23	2.3	0.7	1.3	0.2
		LineB1_ 30	703,1 25	7,780 ,813	P0341	-2mm to +180µm	17	2.4	0.6	0.9	0.2
		LineB1_ 30	703,1 25	7,780 ,813	P0342	-180µm to +75µm	15	2.0	0.6	1.3	0.2
		LineB1_ 30	703,1 25	7,780 ,813	P0343	-75µm	19	3.1	0.8	0.9	0.1
		LineB1_ 31	703,1 45	7,780 ,810	P0344	+2mm	133	6.7	0.5	0.6	0.1
		LineB1_ 31	703,1 45	7,780 ,810	P0345	-2mm to +180µm	128	6.2	0.5	0.6	0.2
		LineB1_ 31	703,1 45	7,780 ,810	P0346	-180µm to +75µm	128	5.6	0.4	0.7	0.1
		LineB1_ 31	703,1 45	7,780 ,810	P0347	-75µm	150	6.9	0.5	0.8	0.1
		LineB1_ 32	703,1 65	7,780 ,807	P0348	+2mm	26	2.1	1.0	1.3	0.1
		LineB1_ 32	703,1 65	7,780 ,807	P0349	-2mm to +180µm	23	1.9	1.1	1.1	0.2
		LineB1_ 32	703,1 65	7,780 ,807	P0351	-180µm to +75µm	22	2.1	1.1	1.0	0.1
		LineB1_ 32	703,1 65	7,780 ,807	P0352	-75µm	25	2.3	1.0	1.3	0.1
		LineB1_ 33	703,1 85	7,780 ,804	P0353	+2mm	36	3.3	4.2	0.8	0.1
		LineB1_ 33	703,1 85	7,780 ,804	P0354	-2mm to +180µm	31	3.0	4.0	0.7	0.1
		LineB1_ 33	703,1 85	7,780 ,804	P0355	-180µm to +75µm	29	3.6	4.8	0.7	0.1
		LineB1_ 33	703,1 85	7,780 ,804	P0356	-75µm	39	4.3	5.5	0.6	0.1
		LineB1_ 34	703,2 05	7,780 ,801	P0357	+2mm	45	2.9	2.9	0.6	0.1
		LineB1_ 34	703,2 05	7,780 ,801	P0358	-2mm to +180µm	44	2.7	2.9	0.7	0.1
		LineB1_ 34	703,2 05	7,780 ,801	P0359	-180µm to +75µm	43	2.0	1.8	0.8	0.1
		LineB1_ 34	703,2 05	7,780 ,801	P0361	-75µm	58	2.8	1.4	0.4	0.1
	Ilapa	LineA1_ 01	703,6 86	7,781 ,545	P0001	+2mm	13	3.3	3.8	1.9	0.2
		LineA1_ 01	703,6 86	7,781 ,545	P0002	-2mm to +180µm	11	3.4	3.8	2.2	0.2
		LineA1_ 01	703,6 86	7,781 ,545	P0003	-180µm to +75µm	12	4.3	5.3	2.3	0.2
		LineA1_ 01	703,6 86	7,781 ,545	P0004	-75µm	11	4.8	5.8	2.5	0.2
		LineA1_ 02	703,7 06	7,781 ,545	P0005	+2mm	21	3.5	4.3	4.7	0.3
		LineA1_ 02	703,7 06	7,781 ,545	P0006	-2mm to +180µm	22	3.8	4.4	3.6	0.1
		LineA1_ 02	703,7 06	7,781 ,545	P0007	-180µm to +75µm	25	4.4	5.3	3.7	0.2
		LineA1_ 02	703,7 06	7,781 ,545	P0008	-75µm	27	4.8	5.9	3.6	0.1
		LineA1_ 03	703,7 26	7,781 ,545	P0009	+2mm	5	1.3	4.6	2.6	0.1
		LineA1_ 03	703,7 26	7,781 ,545	P0010	-2mm to +180µm	5	1.1	4.5	3.1	0.2
		LineA1_ 03	703,7 26	7,781 ,545	P0011	-180µm to +75µm	6	1.4	5.3	4.1	0.2

											17 17 0.1 0.1 0.2 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1
		LineA1_ 03	703,7 26	7,781 ,545	P0012	-75µm	6	1.7	6.1	3.2	0.1
		LineA1_ 04	703,7 46	7,781 ,545	P0013	+2mm	8	1.5	4.8	1.9	0.1
		LineA1_ 04	703,7 46	7,781 ,545	P0014	-2mm to +180µm	9	1.4	4.8	2.1	0.2
		LineA1_ 04	703,7 46	7,781 ,545	P0015	-180µm to +75µm	7	1.3	4.8	1.9	0.1
		LineA1_ 04	703,7 46	7,781 ,545	P0016	-75µm	9	1.5	5.3	1.8	0.1
		LineA1_ 05	703,7 66	7,781 ,545	P0017	+2mm	8	1.1	4.1	1.1	0.1
		LineA1_ 05	703,7 66	7,781 ,545	P0018	-2mm to +180µm	8	0.9	4.2	1.3	0.1
		LineA1_ 05	703,7 66	7,781 ,545	P0019	-180µm to +75µm	8	1.0	4.0	1.3	0.1
		LineA1_ 05	703,7 66	7,781 ,545	P0021	-75µm	8	1.1	4.2	1.4	0.1
		LineA1_ 06	703,7 76	7,781 ,545	P0022	+2mm	12	1.9	7.3	1.2	0.1
		LineA1_ 06	703,7 76	7,781 ,545	P0023	-2mm to +180µm	12	1.8	7.0	1.2	0.1
		LineA1_ 06	703,7 76	7,781 ,545	P0024	-180µm to +75µm	13	1.9	7.1	1.2	0.1
		LineA1_ 06	703,7 76	7,781 ,545	P0025	-75µm	12	2.1	7.6	1.3	0.1
		LineA1_ 07	703,7 86	7,781 ,545	P0026	+2mm	33	2.1	7.6	0.7	0.1
		LineA1_ 07	703,7 86	7,781 ,545	P0027	-2mm to +180µm	33	2.1	8.6	1.0	0.1
		LineA1_ 07	703,7 86	7,781 ,545	P0028	-180µm to +75µm	32	2.2	9.4	1.3	0.1
		LineA1_ 07	703,7 86	7,781 ,545	P0029	-75µm	34	2.5	11.1	1.3	0.1
		LineA1_ 08	703,7 96	7,781 ,545	P0030	+2mm	25	2.8	8.4	1.1	0.1
		LineA1_ 08	703,7 96	7,781 ,545	P0031	-2mm to +180µm	24	2.8	8.2	1.2	0.1
		LineA1_ 08	703,7 96	7,781 ,545	P0032	-180µm to +75µm	24	2.7	8.1	1.0	0.1
		LineA1_ 08	703,7 96	7,781 ,545	P0033	-75µm	34	4.1	12.6	1.4	0.1
		LineA1_ 09	703,8 06	7,781 ,545	P0034	+2mm	16	2.0	5.5	1.7	0.1
		LineA1_ 09	703,8 06	7,781 ,545	P0035	-2mm to +180µm	14	1.7	4.9	1.3	0.1
		LineA1_ 09	703,8 06	7,781 ,545	P0036	-180µm to +75µm	15	2.2	5.7	1.5	0.1
		LineA1_ 09	703,8 06	7,781 ,545	P0037	-75µm	17	2.7	7.3	1.9	0.1
		LineA1_ 10	703,8 11	7,781 ,545	P0038	+2mm	16	2.1	5.1	1.7	0.1
		LineA1_ 10	703,8 11	7,781 ,545	P0039	-2mm to +180µm	15	1.6	4.9	1.9	0.1
		LineA1_ 10	703,8 11	7,781 ,545	P0041	-180µm to +75µm	15	2.1	5.2	1.7	0.1
		LineA1_ 10	703,8 11	7,781 ,545	P0042	-75µm	22	3.0	7.2	2.2	0.1
		LineA1_ 11	703,8 16	7,781 ,545	P0043	+2mm	16	2.5	4.4	1.3	0.1
		LineA1_ 11	703,8 16	7,781 ,545	P0044	-2mm to +180µm	17	2.7	4.3	1.4	0.1
		LineA1_ 11	703,8 16	7,781 ,545	P0045	-180µm to +75µm	17	2.3	4.3	1.4	0.1
		LineA1_ 11	703,8 16	7,781 ,545	P0046	-75µm	22	3.3	5.9	1.7	0.1
		LineA1_ 12	703,8 21	7,781 ,545	P0047	+2mm	38	4.4	5.9	0.5	0.1
		LineA1_ 12	703,8 21	7,781 ,545	P0048	-2mm to +180µm	44	5.9	7.0	0.6	0.1
		LineA1_ 12	703,8 21	7,781 ,545	P0049	-180µm to +75µm	48	5.6	8.0	0.6	0.1

											18 18 0.1 0.1 0.1 0.1 0.1 0.2 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1 0.1
		LineA1_ 12	703,8 21	7,781 ,545	P0051	-75µm	66	7.2	11.3	0.6	0.1
		LineA1_ 13	703,8 26	7,781 ,545	P0052	+2mm	31	3.4	4.8	0.6	0.1
		LineA1_ 13	703,8 26	7,781 ,545	P0053	-2mm to +180µm	30	3.4	5.0	0.5	0.1
		LineA1_ 13	703,8 26	7,781 ,545	P0054	-180µm to +75µm	29	3.3	5.1	0.9	0.1
		LineA1_ 13	703,8 26	7,781 ,545	P0055	-75µm	38	4.5	7.1	507.0	0.1
		LineA1_ 14	703,8 31	7,781 ,545	P0056	+2mm	25	2.5	2.6	0.9	0.2
		LineA1_ 14	703,8 31	7,781 ,545	P0057	-2mm to +180µm	26	2.8	2.9	0.7	0.1
		LineA1_ 14	703,8 31	7,781 ,545	P0058	-180µm to +75µm	14	2.4	2.6	0.8	0.1
		LineA1_ 14	703,8 31	7,781 ,545	P0059	-75µm	16	3.1	3.3	0.9	0.1
		LineA1_ 15	703,8 36	7,781 ,545	P0061	+2mm	15	2.3	3.7	1.1	0.1
		LineA1_ 15	703,8 36	7,781 ,545	P0062	-2mm to +180µm	18	2.6	3.7	1.2	0.1
		LineA1_ 15	703,8 36	7,781 ,545	P0063	-180µm to +75µm	16	2.6	4.1	1.1	0.1
		LineA1_ 15	703,8 36	7,781 ,545	P0064	-75µm	18	2.7	4.9	1.5	0.1
		LineA1_ 16	703,8 41	7,781 ,545	P0065	+2mm	22	2.8	2.4	0.5	0.1
		LineA1_ 16	703,8 41	7,781 ,545	P0066	-2mm to +180µm	22	2.8	2.2	0.5	0.1
		LineA1_ 16	703,8 41	7,781 ,545	P0067	-180µm to +75µm	19	2.7	2.3	0.6	0.1
		LineA1_ 16	703,8 41	7,781 ,545	P0068	-75µm	18	2.9	2.7	0.8	0.1
		LineA1_ 17	703,8 46	7,781 ,545	P0069	+2mm	33	2.9	1.8	0.6	0.1
		LineA1_ 17	703,8 46	7,781 ,545	P0070	-2mm to +180µm	39	3.3	1.9	0.7	0.1
		LineA1_ 17	703,8 46	7,781 ,545	P0071	-180µm to +75µm	24	3.0	2.2	0.8	0.1
		LineA1_ 17	703,8 46	7,781 ,545	P0072	-75µm	27	4.4	2.9	0.7	0.1
		LineA1_ 18	703,8 51	7,781 ,545	P0073	+2mm	25	3.0	2.6	0.8	0.1
		LineA1_ 18	703,8 51	7,781 ,545	P0074	-2mm to +180µm	22	3.0	2.6	0.8	0.1
		LineA1_ 18	703,8 51	7,781 ,545	P0075	-180µm to +75µm	19	2.6	2.6	0.9	0.1
		LineA1_ 18	703,8 51	7,781 ,545	P0076	-75µm	23	3.3	2.9	0.9	0.1
		LineA1_ 19	703,8 56	7,781 ,545	P0077	+2mm	15	2.5	3.2	1.0	0.1
		LineA1_ 19	703,8 56	7,781 ,545	P0078	-2mm to +180µm	17	2.6	3.2	1.0	0.1
		LineA1_ 19	703,8 56	7,781 ,545	P0079	-180µm to +75µm	13	2.7	3.5	1.5	0.1
		LineA1_ 19	703,8 56	7,781 ,545	P0081	-75µm	16	3.3	4.4	1.6	0.1
		LineA1_ 20	703,8 61	7,781 ,545	P0082	+2mm	11	1.2	4.2	1.8	0.1
		LineA1_ 20	703,8 61	7,781 ,545	P0083	-2mm to +180µm	10	1.0	4.1	2.2	0.1
		LineA1_ 20	703,8 61	7,781 ,545	P0084	-180µm to +75µm	10	1.1	4.3	1.8	0.1
		LineA1_ 20	703,8 61	7,781 ,545	P0085	-75µm	13	1.7	5.6	2.8	0.1
		LineA1_ 21	703,8 71	7,781 ,545	P0086	+2mm	12	1.3	3.7	2.0	0.1
		LineA1_ 21	703,8 71	7,781 ,545	P0087	-2mm to +180µm	10	1.3	3.7	2.0	0.1
		LineA1_ 21	703,8 71	7,781 ,545	P0088	-180µm to +75µm	11	1.3	3.8	2.1	0.1

	LineA1_ 21	703,8 71	7,781 ,545	P0089	-75µm	14	1.7	4.9	2.9	0.1
	LineA1_ 22	703,8 81	7,781 ,545	P0091	+2mm	11	1.2	4.0	1.2	0.1
	LineA1_ 22	703,8 81	7,781 ,545	P0092	-2mm to +180µm	10	1.0	3.5	1.4	0.1
	LineA1_ 22	703,8 81	7,781 ,545	P0093	-180µm to +75µm	9	1.1	3.7	1.5	0.1
	LineA1_ 22	703,8 81	7,781 ,545	P0094	-75µm	12	1.6	4.9	1.8	0.1
	LineA1_ 23	703,8 91	7,781 ,545	P0095	+2mm	12	1.4	4.2	1.7	0.1
	LineA1_ 23	703,8 91	7,781 ,545	P0096	-2mm to +180µm	13	1.3	4.1	1.7	0.1
	LineA1_ 23	703,8 91	7,781 ,545	P0097	-180µm to +75µm	12	1.3	3.9	1.7	0.1
	LineA1_ 23	703,8 91	7,781 ,545	P0098	-75µm	15	1.7	5.4	2.2	0.1
	LineA1_ 24	703,9 01	7,781 ,545	P0099	+2mm	11	1.2	4.8	1.5	0.1
	LineA1_ 24	703,9 01	7,781 ,545	P0101	-2mm to +180µm	11	1.1	4.5	1.2	0.2
	LineA1_ 24	703,9 01	7,781 ,545	P0102	-180µm to +75µm	10	1.1	4.3	1.1	0.1
	LineA1_ 24	703,9 01	7,781 ,545	P0103	-75µm	12	1.3	5.1	1.3	0.2
	LineA1_ 25	703,9 21	7,781 ,545	P0104	+2mm	9	0.8	4.4	1.4	0.1
	LineA1_ 25	703,9 21	7,781 ,545	P0105	-2mm to +180µm	9	0.8	4.0	1.5	0.1
	LineA1_ 25	703,9 21	7,781 ,545	P0106	-180µm to +75µm	8	0.7	4.1	2.4	0.1
	LineA1_ 25	703,9 21	7,781 ,545	P0107	-75µm	9	1.0	4.8	2.2	0.1
	LineA1_ 26	703,9 41	7,781 ,545	P0108	+2mm	6	1.3	3.0	1.4	0.1
	LineA1_ 26	703,9 41	7,781 ,545	P0109	-2mm to +180µm	7	1.3	2.9	1.0	0.1
	LineA1_ 26	703,9 41	7,781 ,545	P0110	-180µm to +75µm	6	1.3	3.1	1.2	0.1
	LineA1_ 26	703,9 41	7,781 ,545	P0111	-75µm	7	1.8	4.1	1.4	0.1
	LineA1_ 27	703,9 61	7,781 ,545	P0112	+2mm	8	1.5	2.2	1.5	0.1
	LineA1_ 27	703,9 61	7,781 ,545	P0113	-2mm to +180µm	8	1.4	2.0	1.4	0.1
	LineA1_ 27	703,9 61	7,781 ,545	P0114	-180µm to +75µm	7	1.4	2.2	2.2	0.1
	LineA1_ 27	703,9 61	7,781 ,545	P0115	-75µm	8	1.9	3.0	2.2	0.1
	LineA1_ 28	703,9 81	7,781 ,545	P0116	+2mm	7	0.7	4.4	1.2	0.1
	LineA1_ 28	703,9 81	7,781 ,545	P0117	-2mm to +180µm	7	0.6	4.4	1.4	0.1
	LineA1_ 28	703,9 81	7,781 ,545	P0118	-180µm to +75µm	7	0.7	4.3	1.7	0.1
	LineA1_ 28	703,9 81	7,781 ,545	P0119	-75µm	8	0.8	5.1	1.5	0.1

APPENDIX 3: ROCK CHIP SAMPLE RESULTS

Sample ID	Utm 38sX	Utm 38sY	Lithology	Li (ppm)	Li2O (%)	Be (ppm)	Cs (ppm)	Nb (ppm)	Ta (ppm)
P0133	703,0 23	7,780 ,818	Lithium-bearing pegmatite	16,400	3.53	175.0	176.0	18.0	46.6

											20 20 34.0 36.1 53.7 34.8 143.0 234.0 15.6 24.3 26.1 233.0 19.8 73.9 24.9 12.7 6.2 5.9 67.7 6.0 35.2 9.6 7.9 20.1 7.4 5.8 11.8 29.5 9.9 18.0 18.7 8.9 261.0 264.0 273.0 238.0 55.4 27.5
	Ampatsikahitra	P0134	703,0 25	7,780 ,820	Spodumene	29,500	6.35	2.5	73.8	12.0	34.0
	Ampatsikahitra	P0135	703,0 36	7,780 ,826	Pegmatite	249	0.05	41.0	16.7	295.0	36.1
	Ampatsikahitra	P0136	703,0 46	7,780 ,814	Lithium-bearing pegmatite	14,000	3.01	14.0	252.0	31.0	53.7
	Ampatsikahitra	P0137	703,0 44	7,780 ,814	Spodumene	28,900	6.22	7.0	64.9	22.0	34.8
	Ampatsikahitra	P0138	703,0 52	7,780 ,808	Lithium-bearing pegmatite	13,100	2.82	8.0	159.0	64.0	143.0
	Ampatsikahitra	P0139	703,0 52	7,780 ,808	Lithium-bearing pegmatite	10,500	2.26	13.0	725.0	92.0	234.0
	Ampatsikahitra	P0141	703,0 52	7,780 ,808	Spodumene	16,400	3.53	24.0	80.3	13.0	15.6
	Ampatsikahitra	P0142	703,0 61	7,780 ,816	Lithium-bearing pegmatite	21,400	4.61	10.0	148.0	23.0	24.3
	Ampatsikahitra	P0143	703,0 61	7,780 ,816	Spodumene	25,600	5.51	10.0	86.9	25.0	26.1
	Ampatsikahitra	P0144	703,0 61	7,780 ,816	Lepidolite	28,000	6.03	34.0	5130.0	392.0	233.0
	Ampatsikahitra	P0145	703,0 57	7,780 ,812	Lithium-bearing pegmatite	3,760	0.81	6.0	1530.0	34.0	19.8
	Ampatsikahitra	P0146	703,0 57	7,780 ,812	Lepidolite	29,900	6.44	31.0	5480.0	227.0	73.9
	Ampatsikahitra	P0147	703,0 57	7,780 ,812	Lithium-bearing pegmatite	13,400	2.89	16.0	275.0	20.0	24.9
	Ampatsikahitra	P0148	703,0 57	7,780 ,812	Spodumene	33,200	7.15	2.5	31.8	25.0	12.7
	Ampatsikahitra	P0149	703,0 27	7,780 ,834	Schist	1,120	0.24	35.0	193.0	24.0	6.2
	Ampatsikahitra	P0152	703,0 27	7,780 ,834	Schist	1,780	0.38	16.0	429.0	14.0	5.9
	Ampatsikahitra	P0161	703,0 27	7780 834	Schist	1,530	0.33	17.0	245.0	218.0	67.7
	Ampatsikahitra	P0165	703,0 27	7780 834	Schist	3,020	0.65	12.0	521.0	23.0	6.0
	Ampatsikahitra	P0167	703,0 27	7780 834	Schist	1,610	0.35	24.0	315.0	26.0	35.2
	Ampatsikahitra	P0169	703,0 27	7780 834	Schist	1,040	0.22	48.0	226.0	27.0	9.6
	Ampatsikahitra	P0171	703,0 27	7780 834	Schist	1,370	0.29	17.0	235.0	34.0	7.9
	Ampatsikahitra	P0173	703,0 27	7780 834	Schist	445	0.10	110.0	193.0	89.0	20.1
	Ampatsikahitra	P0175	703,0 27	7780 834	Schist	633	0.14	11.0	124.0	24.0	7.4
	Ampatsikahitra	P0177	703,0 27	7780 834	Schist	715	0.15	22.0	152.0	19.0	5.8
	Ampatsikahitra	P0179	703,0 27	7780 834	Schist	609	0.13	14.0	34.9	91.0	11.8
	Ilapa	P0121	703,8 21	7,781 ,545	Lithium-bearing pegmatite	816	0.18	847.0	620.0	132.0	29.5
	Ilapa	P0122	703,8 21	7,781 ,545	Marble	525	0.11	17.0	96.2	21.0	9.9
	Ilapa	P0123	703,8 21	7,781 ,565	Lithium-bearing pegmatite	3,210	0.69	1510.0	1510.0	30.0	18.0
	Ilapa	P0124	703,8 21	7,781 ,565	Lithium-bearing pegmatite	303	0.07	141.0	154.0	51.0	18.7
	Ilapa	P0125	703,8 21	7,781 ,565	Marble	320	0.07	48.0	4.3	39.0	8.9
	Ilapa	P0201	703,6 64	7,781 ,702	Lithium-bearing pegmatite	22,900	4.93	19.0	5190.0	341.0	261.0
	Ilapa	P0202	703,6 60	7,781 ,695	Lithium-bearing pegmatite	21,600	4.65	23.0	4650.0	315.0	264.0
	Ilapa	P0203	703,6 60	7,781 ,704	Lithium-bearing pegmatite	23,700	5.10	19.0	5420.0	349.0	273.0
	Ilapa	P0204	703,6 59	7,781 ,717	Lithium-bearing pegmatite	27,700	5.96	29.0	5590.0	321.0	238.0
	Tsarafara	P0205	704,7 32	7,781 ,808	Lithium-bearing pegmatite	19,000	4.09	12.0	3700.0	137.0	55.4
	Tsarafara	P0206	704,7 33	7,781 ,790	Lithium-bearing pegmatite	8,360	1.80	10.0	1070.0	57.0	27.5

											21 21 372.0 123.0 168.0 218.0 112.0 20.7 16.7
	Tsararano	P0126	702,8 42	7,778 ,967	Lithium-bearing pegmatite	26,500	5.71	39.0	5540.0	287.0	372.0
	Tsararano	P0127	702,8 13	7,778 ,982	Lithium-bearing pegmatite	14,600	3.14	67.0	2710.0	209.0	123.0
	Tsararano	P0128	702,7 94	7,779 ,015	Lithium-bearing pegmatite	19,400	4.18	80.0	4040.0	197.0	168.0
	Tsararano	P0129	702,8 13	7,779 ,104	Lithium-bearing pegmatite	21,300	4.59	28.0	4710.0	216.0	218.0
	Tsararano	P0130	702,7 90	7,779 ,114	Lithium-bearing pegmatite	16,100	3.47	113.0	3360.0	172.0	112.0
	Vietnam	P0131	704,3 93	7,780 ,970	Lithium-bearing pegmatite	28,900	6.22	900.0	824.0	15.0	20.7
	Vietnam	P0132	704,3 96	7,781 ,000	Lithium-bearing pegmatite	1,800	0.39	20.0	565.0	22.0	16.7

APPENDIX 2: JORC CODE, 2012 EDITION – TABLE 1

Discussion and results within this appendix relate to the Bass Metals Ltd – Millie’s Reward Lithium Project, Madagascar.

Section 1 Sampling Techniques and Data

Criteria		JORC Code explanation		Commentary
	>	Nature and quality of sampling (e.g. cut
		channels, random chips, or specific
		specialised industry standard
		measurement tools appropriate to the
		minerals under investigation, such as	>	Orientation soil samples were collected on
		down hole gamma sounds, or handheld		surface across two known lithium-bearing
		XRF instruments, etc.). These examples		pegmatite prospects. Samples were
		should not be taken as limiting the broad		collected by manual augering (average
		meaning of sampling		depth of 45 cm) on 20m and 10m spacing
				across barren zones and 5m spacing across
	>	Include reference to measures taken to		known lithium-bearing zones. The samples
		ensure sample representivity and the		comprised sieved soils for four fractions, +
		appropriate calibration of any		2mm, -2mm to +180µm, -180µm to +75µm
		measurement tools or systems used.		and -75µm.
Sampling			>	Rock-chip samples were collected on surface
techniques	>	Aspects of the determination of		and included in-situ composite and grab
		mineralisation that are Material to the		samples of pegmatites, lithium-bearing
		Public Report. In cases where ‘industry		pegmatites and host rocks.
		standard’ work has been done this would	>	Channel samples were collected in
		be relatively simple (e.g. ‘reverse		underground tunnel workings and included
		circulation drilling was used to obtain 1 m		in-situ composite samples of pegmatites
		samples from which 3 kg was pulverised		and lithium-bearing pegmatites in the roof
		to produce a 30 g charge for fire assay’).		and wall of the workings on 1-meter
		In other cases more explanation may be		intervals.
		required, such as where there is coarse
		gold that has inherent sampling
		problems. Unusual commodities or
		mineralisation types (e.g. submarine
		nodules) may warrant disclosure of
		detailed information.
	>	Drill type (e.g. core, reverse circulation,
		open-hole hammer, rotary air blast,
		auger, Bangka, sonic, etc.) and details
Drilling techniques		(e.g. core diameter, triple or standard tube, depth of diamond tails, face-	>	Not applicable.
		sampling bit or other type, whether core
		is oriented and if so, by what method,
		etc.).

23 23 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. > Samples were geologically logged and photographed, and geological recording of relevant data was captured on Bass Metals logging templates. All data was codified to a set company codes system as per sampling and logging procedures, which are in place. > All logging included lithology, minerals, weathering, colour, grain size, texture, fabric etc., which is quantitative and is recorded on the logging sheets. 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. > The soil samples were sun dried in the field, and four fractions were sieved, + 2mm, - 2mm to +180µm, -180µm to +75µm and - 75µm. The sieved samples of approx. 100g were packed in Kraft envelopes and sent to a laboratory in Antananarivo (Madagascar) for preparation. Samples were then pulverised so that 85% pass -75µm. > The rock-chip and channel samples were bagged and sent to a laboratory in Antananarivo (Madagascar) for preparation. Samples were oven dried, manually crushed to minus 2mm, split twice through a 50/50 riffle splitter to obtain a representative sub- sample, weighing approx. 100g, and then pulverised so that 85% pass -75µm. > Sample sizes are practical and appropriate for the grain size of the material being sampled. 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 > The pulp samples were sent to an independent laboratory (SGS Randfontein) in South Africa for multi element analysis by aqua regia partial digestion with final analysis by inductively coupled atomic emission spectroscopy (ICP-AES) and mass spectrometry (ICP-MS)for the soil samples

24 24 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 (e.g. standards, blanks, duplicates, external laboratory checks) and whether acceptable levels of accuracy (i.e. lack of bias) and precision have been established. and for multi element analysis by sodium peroxide fusion with final analysis by inductively coupled atomic emission spectroscopy (ICP-AES) and mass spectrometry (ICP-MS) for the rock-chip and channel samples. > Other elements beyond Li that were analysed for included Be, Cs, Ga, Nb, Rb, Sn, Ta, Tl (pathfinder elements) and Ca, K, Cr, Mn, Fe, Ni, Zn, Mg, Al, Si, P, S, V, As, Sr, Mo, Pb, Bi. > Certified lithium standards (GTA-01, GTA-03 and GTA-04), silica blanks (AMIS0305) and duplicates (a second sample of the same interval) were inserted with the dispatch of the samples to an independent laboratory (SGS Randfontein) in South Africa. The insertion rate of standards/blanks were 1 in 20, and duplicates were 2 in 100. > SGS Randfontein Laboratory inserted check samples (blanks, standards and duplicates) to maintain QAQC standards. > All in-house and laboratory standards, blanks and duplicates results were reviewed. Performance of the primary laboratory across all assay batches were within acceptable tolerance levels. 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. > All work was completed by Vato Consulting personnel. > All data was collected initially on paper log sheets in the field. This data was hand entered into spreadsheets and validated by the Principal Geologist. All paper log sheets were scanned, and electronic spreadsheets stored together with the photographs of the geological features logged. > The master collar, lithology and assay database with all photographs are backed- up and stored on an external hard drive. > Metallic Lithium parts per million was converted to percentage and then multiplied by a conversion factor of 2.153 to report Li2O for rock-chipand channel samples. 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. > Hand-held Garmin GPS’s were used to locate sample locations, and interim location coordinates were completed taking average readings up to 5 minutes and with estimated positional errors between 1 and 3 meters. > The WGS84 UTM Zone 38S projection

25 25 > Quality and adequacy of topographic control. system is used at the Millie’s Reward Lithium Project. > Topographical control is considered sufficient for the stage of exploration. 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. > Two orientation soil samples lines were across known lithium-bearing pegmatite prospects with sample spacing of 20m, 10m and 5m. A total of 244 soil samples were collected. > Eighty rock-chip and channel samples were collected across at least five prospects. > The data is not appropriate for use in estimating a Mineral Resource and is not intended for such use. There has been insufficient exploration to define a Mineral Resource. Additional detailed geological mapping, and soil sampling programs are recommended to qualify and quantify the anomalous areas in greater detail prior to drill testing if warranted. No sample compositing has been applied, other than the weighted average calculation of mineralised intercepts in the underground tunnel workings. 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. > Orientation soil samples lines were approximately 90 degrees to the strike of pegmatite and lithological contacts. > Orientation of sample lines is not expected to contribute to sampling bias. Sample security > The measures taken to ensure sample security. > Samples were stored in a secure storage area at the Bass Metals field camp. > Samples bags and/or Kraft envelopes were sealed as soon as sub-sampling was completed and stored securely until dispatch to the laboratoryin South Africa via courier. Audits or reviews > The results of any audits or reviews of sampling techniques and data. > No audits of sampling techniques and data was carried out due to the early stage of the exploration. > It is considered that industry best practice methods have been implemented by the Companyat all stages of exploration.