Source - LSE Regulatory
RNS Number : 1822U
Berkeley Energia Limited
29 July 2022
 

BERKELEY ENERGIA LIMITED

 

NEWS RELEASE | 29 July 2022

 

Quarterly Report June 2022

 

Highlights:

 

·     Appointment of Spanish Based Director

The Company strengthened the Board's technical capacity and Spanish operating experience with the appointment of Mr Francisco Bellón as an Executive Director.

Mr Bellón is a Mining Engineer with more than 25 years of experience in the resources sector, including specialisation in mineral processing. During his career, Mr Bellón has participated in the construction, commissioning and operation of four mines in Spain, two in South America and two in West Africa, working at an executive level for Toronto, New York or Madrid Stock Exchange listed companies, such as Rio Narcea Gold Mines, Lundin Mining, ENDESA and Duro Felguera.

Mr Bellón who is based in Salamanca, joined Berkeley in 2011 as General Manager of Operations, and was subsequently promoted to Chief Operating Officer in 2017. During this period, Mr Bellón has been responsible for the Company's day-to-day operations in Spain, and has overseen the development of the Salamanca Project from the Scoping Study stage through to the completion of the Definitive Feasibility Study and Front End Engineering Design.

Mr Bellón has a Masters Degrees in Mining Engineering and Occupational Health and Safety, Investor Relations Certification from the Madrid Stock Exchange, and is Member of the Australasian Institute of Mining and Metallurgy.

·     European Nuclear Power and Global Uranium Market:

The outlook for nuclear power and the uranium market strengthened further during the quarter, with a number of important recent developments, including:

·      The European Parliament voted to reject objections to the inclusion of natural gas and nuclear power in its taxonomy plan which had been subjected to extensive debate since late 2021. A majority of ministers voted against the effort to block the inclusion of the two fuels/generating technologies. Reportedly, "the result means the European Commission's proposals to include certain nuclear and gas activities within the list of investments that meet the taxonomy requirements, is now due to come into force from the start of 2023, given that the European Council is not expected to object to it".

Further, the European Commission released its proposed "REPowerEU Plan" in response to the Russian invasion of Ukraine. The Plan looks to reduce/eliminate the European Union's dependency on fossil fuel imports from Russia.

·      At the Group of Seven ("G7") meeting held in Germany, the broad-ranging G7 Leader's Communique specifically addressed the Russian aggression in Ukraine and its effects on global energy. Regarding commercial nuclear power, the world leaders stated; "Those countries that opt to use it reaffirm the role of nuclear energy in their energy mix. Those countries recognise its potential to provide affordable low-carbon energy and contribute to the security of energy supply as a source of baseload energy and grid flexibility." 

Recognising the global role of Russian-sourced nuclear fuel, the communique clearly stated; "We will further reduce reliance on civil nuclear and related goods from Russia, including working to assist countries seeking to diversify their supplies. We task our relevant Ministers to evaluate the feasibility and efficiency of these measures urgently."

·      The International Energy Agency ("IEA") released a new report Nuclear Power and Secure Energy Transitions: From Today's Challenges to Tomorrow's Clean Energy Systems that highlights nuclear has an essential part to play in delivering a clean, affordable and secure energy future. According to the IEA's report, a low-carbon, sustainable, affordable and secure energy future needs nuclear.

·      Spain's main opposition party, Partido Popular ("PP"), outlined its economic proposals to deal with the economic and energy crises that the country is currently experiencing. The actions include the resurrection of nuclear power in Spain and "extending the useful life of the reactors" in line with what other European countries are doing. The PP believes that this technology must play a key role in the ecological transition as a support for renewable energies, since the opposite would imply greater gas consumption and therefore greater dependence on countries such as Russia.

Security of supply concerns continued to be raised in Spain given that the country's existing nuclear power and fuel fabrication facilities import approximately 39% (2020) of their required uranium from Russia.

·      President Macron cancelled the plan to close 12 reactors by 2035 and requested the state-owned nuclear operator, EDF, to study the feasibility of prolonging reactor lifespans beyond the statutory 50 years. In addition, his government supports the construction of six European Pressurised Reactors by 2050.

·      Belgium's Nuclear Research Centre announced that it will soon begin working with international partners to evaluate the use case for advanced reactors in Belgium. The agency said it is now operating with a Belgian federal government issued €100 million budget, and allocated €25 million per year for four years, to conduct in-depth research into new nuclear units.

·      A new survey carried out in Finland showed that support for nuclear power is at record highs across the country. The survey noted that nuclear power favourability has been measured continually since 1983, and the latest results have beat all-time highs, as more than 60% of the survey's respondents have a positive attitude towards nuclear power. 11% of Finns have a negative stance toward nuclear energy, with 62% of respondents noting that nuclear power is an important tool for combating climate change.

Finland's Green Party, part of the government coalition, also voted to adopt a fully pro-nuclear stance. The party manifesto now states that nuclear is "sustainable energy" and demands the reform of current energy legislation to streamline the approval process for small modular reactors. It also supports licence extensions for existing nuclear reactors. Finland's is the first Green Party to adopt such a position.

·      Swedish MP, Mats Nordberg, emphasized that in order to help counter the Russian aggression in Ukraine there is a need for "mutual assistance and unity" and called for the restart of nuclear reactors and planning for new reactors. Nordberg observed that "The existing reactors, where possible, should continue to work. We must also continue to plan the launch of new nuclear reactors to make the European Union more self-sufficient in the field of energy resources."

·      Germany disclosed that it is reviewing all options at its disposal to ensure the country's energy supply remains robust amid uncertainty over Russian gas supply. The Economy Ministry stated in July that Germany may extend the life of its three remaining nuclear power plants, as public support increases in the face of growing energy shortages. The three plants - Isar 2, Emsland and Neckarwestheim 2 - which made up 6% of Germany's power production in the first quarter of 2022, are scheduled to close at the end of the year.

·      The UK government released its national energy strategy policy paper outlining that nation's plans for enhanced energy security. Under the energy policy, nuclear would provide up to 25% of the country's electricity by 2050 from up to 24 GWe of nuclear generating capacity. In order to support its ambitious commercial nuclear power goals, the UK will establish the Great British Nuclear Vehicle designed to provide support to nuclear projects "through every stage of the development process.

·      China announced plans to construct a further six nuclear reactors as the country pursues its Net Zero goals, with approval given for Sanmen units 3 and 4, Haiyang 3 and 4, and Lufeng 5 and 6.

·      Japan will have as many as nine nuclear power reactors in operation this winter, stated Prime Minister Fumio Kishida. With five reactors currently online, the move will boost combined capacity from nuclear to around 10% of the country's electricity needs. "We want to have ample capacity to ensure a stable supply of electricity during peak times," Kishida said. "The national government will take the lead" on restarting these reactors, "making tenacious efforts to secure the understanding and cooperation of local governments and other stakeholders."

·      South Korea released its revised energy policy which sets the goal of maintaining nuclear power's share of total electricity generation at a minimum of 30% by 2030.

Newly-elected President, Yoon Suk-yeol announced the construction of two reactors would resume immediately. The Ministry of Trade, Industry and Energy also commented that in response to the global goals of carbon neutrality and the Russia-Ukraine conflict which threatens global energy security supply chains, "it is imperative that new energy policy goals and directions are set to better accomplish carbon neutral government projects and the expansion of nuclear power." Included in the energy policy are the goals of exporting 10 nuclear power plants by 2030 as well as the development of a Korean small modular reactor design.

The Uranium spot price closed at US$49.00 per pound at the end of June 2022, with the spot market volume increasing to 3.3 million pounds, more than 40% up from the May total volumes.

Longer-term uranium price indicators continued to rise steadily with a 23.5% increased year to date.  At the end of June, prices closed at US$50.00 per pound (Long-Term); US$54.50 per pound (3-year forward price); and US$57.25 per pound (5-year forward price).

·     Balance Sheet

The Company is in a strong financial position with A$80 million in cash reserves and no debt.

 

For further information please contact:

 

Robert Behets                                            Franciso Bellón           

Acting Managing Director                            Executive Director

+61 8 9322 6322                                          +34 923 193 903

info@berkeleyenergia.com

 

Salamanca Project Summary

The Salamanca Project ("Salamanca" or "Project") is being developed in an historic uranium mining area in Western Spain about three hours west of Madrid.

The Project hosts a Mineral Resource of 89.3Mlb uranium, with more than two thirds in the Measured and Indicated category. In 2016, Berkeley published the results of a robust Definitive Feasibility Study ("DFS") for Salamanca confirming that the Project will be one of the world's lowest cost producers, capable of generating strong after-tax cash flows. The DFS was based solely on Measured and Indicated Resources, with the following key study outputs and economics:

·      Producing 4.4 million pounds of uranium per annum (steady state operation)

·      Initial mine life of 14 years

·      Uranium prices based on UxC annual mid-long term base price projection (US$39.06 per pound (2017) - US$67.69 per pound (2030))

·      Initial capital cost of US$95.7 million

·      Operating costs of US$15.39 per pound

·      Post-tax NPV8 of US$531.9 million

·      Post-tax IRR of 60%

In 2021, the Company received formal notification from Ministry for Ecological Transition and the Demographic Challenge ("MITECO") that it had rejected the Authorisation for Construction for the uranium plant as a radioactive facility ("NSC II") application at Salamanca. This decision followed the unfavourable NSC II report issued by the Nuclear Safety Council ("NSC") in July 2021.

The Company continues to strongly defend its position in relation to the adverse resolution by MITECO and has submitted an administrative appeal against the decision under Spanish law.

In Berkeley's strong opinion, MITECO has rejected the Company's NSC II application without following a legally established procedure and the Company believes that MITECO has infringed regulations on administrative procedures in Spain, as well as Berkeley's right of defence, which would imply that the decision on the rejection of the Company's NSC II application is not legal.

NSC II is the only key approval required to commence full construction of the Salamanca mine.

The Salamanca mine is being developed to the highest international standards and the Company's commitment to health, safety and the environment is a priority. Berkeley holds certificates in Sustainable Mining (UNE 22470-80) and Environmental Management (ISO 14001) which were awarded by AENOR, an independent Spanish government agency.

These management systems ensure that Company procedures are compliant with current regulations, ensure that the environment is protected, the project is sustainable, and that all activities are carried out with respect for and in collaboration with the local communities.

Berkeley's efforts in the key area of Sustainable Mining have been independently recognised with it being selected as the winner of the Outstanding Contribution to Sustainable Mining - Europe category in the 2020 Capital Finance International Sustainability Awards.

The Company is in a strong financial position with A$80 million in cash reserves and no debt.

Project Update:

The Company continued with its commitment to health, safety and the environment as a priority.

During the June 2022 quarter, the Company measured and reported its performance against its planned 2021 objectives in the areas of health, safety, environment and sustainability.

The Sustainability Performance Report is a voluntary transparency initiative through which the Company openly communicates information regarding its management systems in the areas of health, safety, environmental protection and social responsibility, as well as its performance in sustainability, to all stakeholders.

The Sustainability Performance Report, which provides a detailed overview of environmental, social and governance ("ESG") activities over the 12-month period to 31 December 2021, has been distributed to key stakeholders.

A copy of the Sustainable Performance Report can be found on the Company's website at:  www.berkeleyenergia.com/sustainable-mining/.

Berkeley is committed to sustainable development, and accordingly has implemented Environmental and Sustainable Management Systems to ensure compliance with performance standards. The UNE 22470-80 standard for Sustainable Mining Management has established 55 indicators that are certified annually. Of these 55 indicators, 36 are currently applicable to Berkeley's Salamanca Project. These are divided into: economic (5), social (19) and environmental (12) categories.

Highlights from the 2021 performance include:

·      R&D investment by the Company increased by 5%.

·      74% of consumables acquired by the Company were sourced locally i.e. promoting the socioeconomic development of the province.

·      Investment in environmental protection increased by 55% compared to previous year

Also noteworthy is the 29% reduction achieved in energy consumption, derived from fuel and electricity consumption. These energy savings minimise resource depletion and contribute to a decrease in CO2 emissions into the atmosphere. During 2021, The Company reduced CO2 emissions by ~28% or the equivalent of eight tonnes of CO2 emissions to the atmosphere.

The Company continued its strong engagement with key stakeholders at a local, regional and federal level in Spain during the quarter.

Exploration:

The Company continued with its exploration program focusing on battery and critical metals in Spain.

The exploration program is targeting lithium, cobalt, tin, tungsten and rare earths, within the Company's existing tenement package in western Spain. Further analysis of the mineral and metal endowment across the entire mineral rich province and other prospective regions in Spain is also being undertaken, with a view to identifying additional targets and regional consolidation opportunities.

Whilst Berkeley remains focused on defending its position in relation to the adverse resolution by MITECO and ultimately advancing the Salamanca project towards production, the planned battery and critical metals exploration initiative also facilitates the Company's participation in these important, rapidly evolving, growth sectors which are integral to the global clean energy transition.

Investigation Permit Conchas

The Investigation Permit ("I.P.") Conchas is located ~10km south of Berkeley's Alameda deposit, in the very western part of Salamanca province, close to the Portuguese border.

The tenement covers an area of ~31km2 in the western part of the Ciudad Rodrigo Basin and is largely covered by Cenozoic aged sediments. Only the north-western part of the tenement is uncovered and dominated by the Guarda Batholith (Vilar Formoso-Fuentes de Oñoro sector) intrusion. The tenement hosts a number of sites where small-scale historical tin and tungsten mining was undertaken. In addition, several mineral occurrences (tin, tungsten, titanium, lithium) have been identified during historical mapping or stream sediment sampling programs.

The Company completed initial soil sampling programs in northern and central portions of the tenement during 2021. The sampling, which was undertaken on a 200m by 200m grid, defined a tin-lithium anomaly covering approximately 1.1km by 0.7km which correlated with a mapped aplo-pegmatitic leucogranite.

During the quarter, an infill and extension soil sampling program was undertaken to follow-up the 2021 results. A total of 116 samples was collected to close the grid down to a 100m by 100m spacing over the previous defined anomaly, and extend the coverage to the east on a 200m by 200m grid. The samples were subsequently prepared and sent to ALS Seville for analysis.

The results of the infill soil sampling program have confirmed the spatial location, scale and tenor of the tin-lithium anomaly defined in 2021 but failed to extend the anomalism to the east (Figure 2).

The Company has also recently obtained a report summarising exploration work undertaken by Billiton PLC on the I.P. Conchas between 1981 and 1983. Billiton's exploration was focused on tin and tantalum and comprised regional and detailed geological mapping, geochemistry, trenching and limited drilling.

The results of Berkeley's recent soil sampling program are encouraging and the Company is currently verifying, evaluating and incorporating the additional historical information contained in the Billiton report, with a view to planning the next phase of exploration activity to assess the tin-lithium anomaly.

Corporate

Settlement of OIA Claim:

During the quarter, Berkeley announced that the OIA Claim brought against the Company in relation to the investment agreement and convertible note had been settled with the parties agreeing to discontinue legal proceedings in the Supreme Court of Western Australia.

Appointment of Spanish Based Director:

During the quarter, the Company announced the appointment of Mr Francisco Bellón as an Executive Director of the Company effective 1 July 2022.

Mr Bellón who is based in Salamanca, joined Berkeley in 2011 as General Manager of Operations, and was subsequently promoted to Chief Operating Officer in 2017. During this period, Mr Bellón has been responsible for the Company's day-to-day operations in Spain, and has overseen the development of the Salamanca Project from the Scoping Study stage through to the completion of the Definitive Feasibility Study and Front End Engineering Design. He has also been a Director of the Company's Spanish subsidiaries since 2011.

The appointment of Mr Bellón will substantially strengthen the Board's technical capacity and Spanish operating experience as the Company continues to focus on resolving the current permitting situation, and ultimately advancing the Salamanca project towards production.

Additional Information on the European Nuclear Power and Global Uranium Market:

The outlook for nuclear power and the uranium market strengthened further during the quarter, with a number of important recent developments, including:

·      The European Parliament voted to reject objections to the inclusion of natural gas and nuclear power in its taxonomy plan which had been subjected to extensive debate since late 2021. A majority (353) of MEPs voted against the effort to block the inclusion of the two fuels/generating technologies while 278 MEPs voted in favour of the measure. Reportedly, "the result means the European Commission's proposals to include certain nuclear and gas activities within the list of investments that meet the taxonomy requirements, is now due to come into force from the start of 2023, given that the European Council is not expected to object to it".

Further, in May 2022, the European Commission released its proposed "REPowerEU Plan" in response to the Russian invasion of Ukraine. The Plan looks to reduce/eliminate the European Union's dependency on fossil fuel imports from Russia.

·      At the conclusion of the G7 meeting held in Germany during the quarter, the broad-ranging G7 Leader's Communique specifically addressed the Russian aggression in Ukraine and its effects on global energy. The communique stated; "We reaffirm our commitment to phase out our dependency on Russian energy" and furthermore, "we will explore further measures to prevent Russia from profiting from its war of aggression." Regarding commercial nuclear power, the world leaders stated; "Those countries that opt to use it reaffirm the role of nuclear energy in their energy mix. Those countries recognise its potential to provide affordable low-carbon energy and contribute to the security of energy supply as a source of baseload energy and grid flexibility." 

Recognising the global role of Russian-sourced nuclear fuel, the communique clearly stated; "We will further reduce reliance on civil nuclear and related goods from Russia, including working to assist countries seeking to diversify their supplies. We task our relevant Ministers to evaluate the feasibility and efficiency of these measures urgently."

·      The International Energy Agency ("IEA") released a new report Nuclear Power and Secure Energy Transitions: From Today's Challenges to Tomorrow's Clean Energy Systems that looks at how nuclear energy could help address two major crises - energy and climate - facing the world today. The report highlights that nuclear has an essential part to play in delivering a clean, affordable and secure energy future. According to the IEA's report, a low-carbon, sustainable, affordable and secure energy future needs nuclear.

·      Spain's main opposition party, Partido Popular ("PP"), outlined its economic proposals to deal with the economic and energy crises that the country is currently experiencing. The actions include the resurrection of nuclear power in Spain and "extending the useful life of the reactors" in line with what other European countries are doing. The PP believes that this technology must play a key role in the ecological transition as a support for renewable energies, since the opposite would imply greater gas consumption and therefore greater dependence on countries such as Russia.

Security of supply concerns continued to be raised in Spain given that the country's existing nuclear power and fuel fabrication facilities import approximately 39% (2020) of their required uranium from Russia.

·      After winning a second term in office during national elections, President Macron cancelled the plan to close 12 reactors by 2035 and requested the state-owned nuclear operator, EDF, to study the feasibility of prolonging reactor lifespans beyond the statutory 50 years. In addition, his government supports the construction of six European Pressurized Reactors by 2050.

·      Belgium's Nuclear Research Centre (SCK CEN) announced in May that it will soon begin working with international partners to evaluate the use case for advanced reactors in Belgium. The agency said it is now operating with a Belgian federal government issued €100 million budget, and allocated €25 million per year for four years, to conduct in-depth research into new nuclear units.

·      A new survey carried out in Finland during the quarter shows that support for nuclear power is at record highs across the country. The survey noted that nuclear power favourability has been measured continually since 1983, and the latest results have beat all-time highs, as more than 60% of the survey's respondents have a positive attitude towards nuclear power. 11% of Finns have a negative stance toward nuclear energy, with 62% of respondents noting that nuclear power is an important tool for combating climate change.

Finland's Green Party, part of the government coalition, voted to adopt a fully pro-nuclear stance at its annual conference in May. The party manifesto now states that nuclear is "sustainable energy" and demands the reform of current energy legislation to streamline the approval process for small modular reactors. It also supports licence extensions for existing nuclear reactors. Finland's is the first Green Party to adopt such a position.

·      In his comments before a conference held in the Guildhall-London in June, Swedish MP, Mats Nordberg, emphasized that in order to help counter the Russian aggression in Ukraine there is a need for "mutual assistance and unity" and called for the restart of nuclear reactors and planning for new reactors.

Nordberg observed that "The existing reactors, where possible, should continue to work. We must also continue to plan the launch of new nuclear reactors to make the European Union more self-sufficient in the field of energy resources."

·      Germany disclosed that it is reviewing all options at its disposal to ensure the country's energy supply remains robust amid uncertainty over Russian gas supply. The Economy Ministry stated in July that Germany may extend the life of its three remaining nuclear power plants, as public support increases in the face of growing energy shortages. The three plants - Isar 2, Emsland and Neckarwestheim 2 - which made up 6% of Germany's power production in the first quarter of 2022, are scheduled to close at the end of the year.

·      The UK government released its national energy strategy policy paper during the quarter outlining that nation's plans for enhanced energy security. Under the energy policy, nuclear would provide up to 25% of the country's electricity by 2050 from up to 24 GWe of nuclear generating capacity. In order to support its ambitious commercial nuclear power goals, the UK will establish the Great British Nuclear Vehicle designed to provide support to nuclear projects "through every stage of the development process.

·      China announced plans to construct a further six nuclear reactors as the country pursues its Net Zero goals. During an executive meeting of the State Council, approval was given for Sanmen units 3 and 4, Haiyang 3 and 4, and Lufeng 5 and 6.

·      Japan will have as many as nine nuclear power reactors in operation this winter, stated Prime Minister Fumio Kishida. With five reactors currently online, the move will boost combined capacity from nuclear to around 10% of the country's electricity needs. "We want to have ample capacity to ensure a stable supply of electricity during peak times," Kishida said. "The national government will take the lead" on restarting these reactors, "making tenacious efforts to secure the understanding and cooperation of local governments and other stakeholders."

·      South Korea released its revised energy policy which sets the goal of maintaining nuclear power's share of total electricity generation at a minimum of 30% by 2030

Newly-elected President, Yoon Suk-yeol announced the construction of two reactors would resume immediately. In its statement before the 30th State Council meeting, the Ministry of Trade, Industry and Energy commented that in response to the global goals of carbon neutrality and the Russia-Ukraine conflict which threatens global energy security supply chains, "it is imperative that new energy policy goals and directions are set to better accomplish carbon neutral government projects and the expansion of nuclear power."

Included in the energy policy are the goals of exporting 10 nuclear power plants by 2030 as well as the development of a Korean small modular reactor design.

Forward Looking Statements

Statements regarding plans with respect to Berkeley's mineral properties are forward-looking statements. There can be no assurance that Berkeley's plans for development of its mineral properties will proceed as currently expected. There can also be no assurance that Berkeley will be able to confirm the presence of additional mineral deposits, that any mineralisation will prove to be economic or that a mine will successfully be developed on any of Berkeley mineral properties. These forward-looking statements are based on Berkeley'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 Berkeley, which could cause actual results to differ materially from such statements. Berkeley 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.

Competent Persons Statement

The information in this report that relates to Exploration Results is based on, and fairly represents, information compiled by Mr Enrique Martínez, a Competent Person who is a Member of the Australasian Institute of Mining and Metallurgy. Mr Martínez is Berkeley's Geology Manager and a holder of shares and options in Berkeley. Mr Martínez 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 Martínez 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 report that relates to the DFS, Mineral Resources, Ore Reserve Estimates, Mining, Uranium Preparation, Infrastructure, Production Targets and Cost Estimation is extracted from the announcement entitled 'Study confirms the Salamanca project as one of the world's lowest cost uranium producers' dated 14 July 2016, which is available to view on Berkeley's website at www.berkeleyenergia.com.

Berkeley confirms that: a) it is not aware of any new information or data that materially affects the information included in the original announcement; b) all material assumptions and technical parameters underpinning the Mineral Resources, Ore Reserve Estimate, Production Target, and related forecast financial information derived from the Production Target included in the original announcement continue to apply and have not materially changed; and c) the form and context in which the relevant Competent Persons' findings are presented in this announcement have not been materially modified from the original announcements.

To view this announcement in full, including all figures and illustrations, please refer to www.berkeleyenergia.com.

Appendix 1: Mineral Resource at Salamanca

Deposit

Name

Resource Category

Tonnes

(Mt)

U3O8

(ppm)

U3O8

(Mlbs)

Retortillo

Measured

4.1

498

4.5

 

Indicated

11.3

395

9.8


Inferred

0.2

368

0.2


Total

15.6

422

14.5

Zona 7

Measured

Indicated

5.2

10.5

674

761

7.8

17.6

 

Inferred

6.0

364

4.8

 

Total

21.7

631

30.2

Alameda

Indicated

20.0

455

20.1


Inferred

0.7

657

1.0

 

Total

20.7

462

21.1

Las Carbas

Inferred

0.6

443

0.6

Cristina

Inferred

0.8

460

0.8

Caridad

Inferred

0.4

382

0.4

Villares

Inferred

0.7

672

1.1

Villares North

Inferred

0.3

388

0.2

Total Retortillo Satellites

Total

2.8

492

3.0

Villar

Inferred

5.0

446

4.9

Alameda Nth Zone 2

Inferred

1.2

472

1.3

Alameda Nth Zone 19

Inferred

1.1

492

1.2

Alameda Nth Zone 21

Inferred

1.8

531

2.1

Total Alameda Satellites

Total

9.1

472

9.5

Gambuta

Inferred

12.7

394

11.1

Salamanca Project Total

Measured

9.3

597

12.3

Indicated

41.8

516

47.5

Inferred

31.5

395

29.6

Total (*)

82.6

514

89.3

 

Appendix 2: Summary of Mining Tenements

As at 30 June 2022, the Company had an interest in the following tenements:

 

Location

Tenement Name

Percentage Interest

Status

Spain




Salamanca

D.S.R Salamanca 28 (Alameda)

100%

Granted


D.S.R Salamanca 29 (Villar)

100%

Granted


E.C. Retortillo-Santidad

100%

Granted


E.C. Lucero

100%

Pending


I.P. Abedules

100%

Granted


I.P. Abetos

100%

Granted


I.P. Alcornoques

100%

Granted


I.P. Alisos

100%

Granted


I.P. Bardal

100%

Granted


I.P. Barquilla

100%

Granted


I.P. Berzosa

100%

Granted


I.P. Campillo

100%

Granted


I.P. Castaños 2

100%

Granted


I.P. Ciervo

100%

Granted


I.P. Conchas

100%

Granted


I.P. Dehesa

100%

Granted


I.P. El Águila

100%

Granted


I.P. El Vaqueril    

100%

Granted


I.P. Espinera

100%

Granted


I.P. Horcajada

100%

Granted


I.P. Lis

100%

Granted


I.P. Mailleras

100%

Granted


I.P. Mimbre

100%

Granted


I.P. Pedreras

100%

Granted


E.P. Herradura*

100%

Granted

Cáceres

I.P. Almendro

100%


I.P. Ibor

100%

Granted


I.P. Olmos

100%

Granted

*An application for a 1-year extension at E.P. Herradura was previously rejected however this decision has been appealed and the Company awaits the decision regarding its appeal.

 

Appendix 3: Related Party Payments

During the quarter ended 30 June 2022, the Company made payments of $130,000 to related parties and their associates. These payments relate to existing remuneration arrangements (director and consulting fees plus statutory superannuation).

Appendix 4: Exploration and Mining Expenditure

 

During the quarter ended 30 June 2022, the Company made the following payments in relation to exploration and development activities:

 

Activity

$000

Radiological protection and monitoring

(9)

Permitting related expenditure (including legal expenses)

(266)

Consultants and other expenditure

(196)

Return of VAT in Spain

32

Total as reported in the Appendix 5B

(439)

 

There were no mining or production activities and expenses incurred during the quarter ended 30 June 2022.



 

Appendix 5: Summary of Soil Sampling Results - I.P. Conchas

 

Sample ID

Easting (m)

Northing (m)

Li (ppm)

Sn (ppm)

Nb (ppm)

Ta (ppm)

49277

683,494

4,494,099

38

90

9.9

1.8

49278

683,704

4,494,104

32

14

6.7

1.3

49279

683,904

4,494,102

60

35

9.3

1.8

49280

684,116

4,494,094

82

14

8.7

1.4

49281

684,302

4,494,099

77

60

13.0

1.8

49282

684,499

4,494,099

49

300

15.2

4.3

49283

684,701

4,494,099

95

125

17.3

7.0

49284

685,098

4,494,093

95

29

12.3

1.9

49285

683,504

4,493,899

86

23

14.0

2.3

49286

683,504

4,493,899

89

20

14.6

2.2

49287

683,730

4,493,925

91

34

14.4

2.3

49288

683,902

4,493,897

73

71

13.6

2.6

49289

684,102

4,493,897

86

50

14.4

1.8

49290

684,298

4,493,899

57

29

14.6

2.2

49291

684,501

4,493,899

105

151

21.3

8.7

49292

684,706

4,493,901

78

27

12.6

2.3

49293

684,900

4,493,901

119

32

15.0

3.1

49294

685,097

4,493,900

98

42

13.2

2.9

49295

683,498

4,493,698

41

31

9.8

1.8

49296

683,697

4,493,705

40

23

13.4

2.2

49297

683,898

4,493,701

77

17

16.0

2.3

49298

684,098

4,493,701

58

21

10.2

1.5

49299

684,297

4,493,704

119

45

15.4

2.2

49300

684,297

4,493,704

125

46

15.5

2.2

49301

684,502

4,493,697

88

79

13.9

2.2

49302

684,700

4,493,704

76

80

11.4

2.0

49303

684,898

4,493,703

69

37

9.9

1.6

49304

684,898

4,493,703

81

75

13.2

2.2

49305

685,097

4,493,700

70

35

12.7

2.2

49306

683,496

4,493,498

52

35

10.8

1.9

49307

683,496

4,493,498

53

45

12.4

2.2

49308

683,704

4,493,499

43

28

10.9

1.8

49309

683,898

4,493,499

83

245

15.5

4.2

49310

684,099

4,493,499

59

29

9.2

1.4

49311

684,299

4,493,499

58

34

9.0

4.7

49312

684,499

4,493,499

45

24

10.1

4.3

49313

684,701

4,493,499

55

34

14.0

6.2

49314

683,701

4,493,297

37

22

10.2

5.9

49315

683,898

4,493,299

40

23

12.1

9.8

49316

684,089

4,493,302

42

65

10.1

5.2

49317

684,299

4,493,300

38

43

10.2

5.0

49318

684,507

4,493,302

55

217

17.6

8.8

Sample ID

Easting (m)

Northing (m)

Li (ppm)

Sn (ppm)

Nb (ppm)

Ta (ppm)

49319

684,705

4,493,304

37

70

4.7

1.5

49320

684,901

4,493,303

53

208

12.4

3.8

49321

685,099

4,493,297

108

28

11.7

1.6

49322

683,899

4,493,098

47

64

17.6

10.5

49323

684,099

4,493,104

44

43

9.2

6.3

49324

684,295

4,493,099

49

21

9.8

7.5

49325

684,504

4,493,100

48

91

13.0

8.5

49326

684,700

4,493,101

240

729

25.5

21.1

49327

684,897

4,493,095

70

428

19.6

13.1

49328

685,101

4,493,099

81

93

18.0

10.2

49329

683,898

4,492,901

43

37

12.2

2.2

49330

684,101

4,492,901

630

622

49.6

41.7

49331

684,304

4,492,904

580

353

36.9

23.5

49332

684,500

4,492,902

400

473

40.3

25.5

49333

684,702

4,492,902

219

128

39.5

25.8

49334

684,901

4,492,900

108

49

14.7

2.8

49335

685,094

4,492,898

45

111

10.5

2.9

49336

683,901

4,492,702

41

40

10.6

1.9

49337

684,099

4,492,700

39

24

7.7

1.6

49338

684,296

4,492,700

53

58

12.2

2.9

49339

684,296

4,492,700

54

63

11.6

2.8

49340

684,501

4,492,700

96

155

13.9

9.0

49341

684,701

4,492,700

121

177

23.0

11.3

49342

684,901

4,492,703

110

104

14.6

3.6

49343

685,097

4,492,700

34

56

13.5

2.9

49344

684,101

4,492,497

35

72

10.2

2.2

49345

684,301

4,492,501

450

251

28.6

18.0

49346

684,497

4,492,496

171

198

21.2

10.5

49347

684,696

4,492,501

72

261

17.4

7.7

49348

684,902

4,492,504

98

81

18.4

5.8

49349

685,097

4,492,502

35

102

13.5

2.6

49350

684,112

4,492,296

65

128

12.7

3.5

49351

684,304

4,492,300

76

76

10.7

4.2

49352

684,304

4,492,300

86

68

11.2

4.2

49353

684,494

4,492,298

128

196

18.2

9.7

49354

684,494

4,492,298

151

256

22.5

13.3

49355

684,700

4,492,298

139

209

24.6

7.5

49356

684,903

4,492,301

26

85

11.6

2.7

49357

685,101

4,492,297

34

54

16.0

3.5

49358

684,301

4,492,100

980

1200

92.6

83.3

49359

684,501

4,492,106

270

219

24.3

10.6

49360

684,701

4,492,097

52

76

12.3

4.0

49361

684,891

4,492,102

30

56

11.8

3.2

Sample ID

Easting (m)

Northing (m)

Li (ppm)

Sn (ppm)

Nb (ppm)

Ta (ppm)

49362

685,101

4,492,104

21

42

13.0

2.5

49363

684,714

4,491,904

53

18

12.3

1.7

49364

684,899

4,491,905

17

20

11.2

2.0

49365

685,100

4,491,898

48

231

27.7

43.0

49366

685,201

4,493,389

95

37

14.8

2.3

49367

685,199

4,493,203

116

48

17.4

2.5

49368

685,396

4,493,199

52

50

12.7

2.4

49369

685,598

4,493,199

41

170

17.4

4.3

49370

685,202

4,493,003

48

84

8.3

2.1

49371

685,399

4,493,001

42

65

13.3

2.3

49372

685,595

4,492,998

47

95

16.2

3.6

49373

685,205

4,492,798

41

34

12.8

2.1

49374

685,205

4,492,798

44

105

14.3

3.3

49375

685,397

4,492,800

42

70

14.3

3.1

49376

685,600

4,492,797

42

107

15.2

3.2

49377

685,203

4,492,604

34

32

12.2

2.3

49378

685,402

4,492,601

38

42

14.2

2.4

49379

685,602

4,492,599

37

66

14.0

3.4

49380

685,199

4,492,403

33

72

14.0

3.1

49381

685,402

4,492,399

34

96

16.0

4.5

49382

685,601

4,492,404

42

162

16.6

3.3

49383

685,201

4,492,200

25

29

10.8

2.7

49384

685,400

4,492,202

51

554

27.6

11.0

49385

685,595

4,492,198

32

106

14.5

5.2

49386

685,197

4,491,996

45

146

17.9

4.8

49387

685,368

4,491,956

37

87

13.8

3.1

49388

685,596

4,491,997

33

85

15.4

3.7

49389

685,596

4,491,997

33

108

12.7

2.8

49390

685,196

4,491,798

36

54

17.6

3.6

49391

685,398

4,491,798

33

85

16.2

3.5

49392

685,597

4,491,799

25

50

11.2

2.6

 

Appendix 6:  JORC Code, 2012 Edition - Table 1 Report

Section 1 Sampling Techniques and Data

(Criteria in this section apply to all succeeding sections.)

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.

The I.P. Conchas sampling includes 116 soil and QA/QC samples. Soil samples are collected over igneous rocks of the Guarda Batholith (Vilar Formoso-Fuentes de Oñoro sector) at the grass root zone, between 15cm and 20cm depth. One sample is collected at each location.

 

Include reference to measures taken to ensure sample representivity and the appropriate calibration of any measurement tools or systems used.

Field duplicate samples are inserted to assess the variability of the mineralisation. Approximately 10% of all samples relate to quality control. In addition, the laboratories undertake their own duplicate sampling as part of their internal QA/QC processes. Examination of the QA/QC sample data indicates satisfactory performance of field sampling protocols and assay laboratories providing acceptable levels of precision and accuracy.

 

 

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.

Soil samples are collected between 15cm and 20cm depth using a small shovel. The average weight per sample is approximately 0.5kg. One sample is collected at each location.

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).

No drilling completed.

Drill sample recovery

Method of recording and assessing core and chip sample recoveries and results assessed.

 

No drilling completed.

 

Measures taken to maximise sample recovery and ensure representative nature of the samples.

No drilling completed.

 

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.

No drilling completed.

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.

No drilling completed.

 

Whether logging is qualitative or quantitative in nature. Core (or costean, channel, etc) photography.

A short field description of each soil sample was collected, including colour and regolith.

 

The total length and percentage of the relevant intersections logged.

No drilling completed.

Sub-sampling techniques

If core, whether cut or sawn and whether quarter, half or all core taken.

No drilling completed.

 

and sample preparation

If non-core, whether riffled, tube sampled, rotary split, etc and whether sampled wet or dry.

Soil samples sieved and collected dry to slightly moist. Samples are allowed to air dry before being sent to the laboratory.

 

For all sample types, the nature, quality and appropriateness of the sample preparation technique.

Samples are sent to ALS laboratory for preparation. Samples are pulverised with at least 85% of the sample passing 75µm. 0.2g of sample is used for analysis by ICP method. This is considered appropriate for this style of mineralisation.

 

Quality control procedures adopted for all sub-sampling stages to maximise representivity of samples.

The laboratory reports results for internal standards, duplicates, prep duplicates and blanks.

 

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.

Field duplicates are inserted into sample batches at a frequency of approximately 10%.

 

Whether sample sizes are appropriate to the grain size of the material being sampled.

The sample weights average 0.4kg, this is considered appropriate for 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.

Analysis is by ALS Method ME-MS89LTM, which uses a sodium peroxide fusion with ICP finish. The method is considered a total technique with 53 elements reported.

 

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.

No geophysical surveys conducted.

 

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.

Field duplicates are regularly inserted into the sample stream with approximately 10% of all samples related to quality control. The external laboratories used also maintain their own process of QA/QC utilising standards, pulp repeats, sample duplicates and blanks.

 

Review of Berkeley's quality control samples, as well as the external laboratory quality QA/QC reports, has shown no sample preparation issues, acceptable levels of accuracy and precision and no bias in the analytical datasets.

Verification of sampling and assaying

The verification of significant intersections by either independent or alternative company personnel.

 

No drilling completed.

 

The use of twinned holes.

No drilling completed.

 

Documentation of primary data, data entry procedures, data verification, data storage (physical and electronic) protocols.

All primary data is recorded in templates designed by Berkeley. Assay data from the external laboratory is received in spreadsheets and downloaded directly into the spreadsheet. Data is entered into controlled excel templates for validation.

GPS locations are downloaded directly to a GIS platform and then copy and paste in the master spreadsheet.

 

Discuss any adjustment to assay data.

None applied.

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.

Soil sample locations were collected using a handheld GPS unit which has an accuracy of approximately +/- 5m.

 

Specification of the grid system used.

The grid system is ETRS 1989 UTM Zone 29N.

 

Quality and adequacy of topographic control.

Topographic control is based on a digital terrain model with sub metric accuracy sourced from the Spanish Geographical Institute (Instituto Geográfico Nacional).

Data spacing and distribution

Data spacing for reporting of Exploration Results.

I.P. Conchas soil samples collected on approximately 200 x 200m grid.

 

 

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.

Existing data not applicable to estimate mineral resources.

 

Whether sample compositing has been applied.

No compositing applied.

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.

Shallow parts of the deposit show that the mineralised zone is rounded without preferred direction. Grid sampling is oriented NS-EW.

 

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.

No drilling completed.

Sample security

The measures taken to ensure sample security.

Chain of custody is managed by Berkeley. Samples are transported from the sample site by Company vehicle to a sample preparation shed where samples are prepared for dispatch. Samples are sent directly from the sample preparation shed to the laboratory using a certified courier. Sample submission forms are sent in paper form with the samples as well as electronically to the laboratory. Reconciliation of samples occurs prior to commencement of sample preparation for assaying.

Audits or reviews

The results of any audits or reviews of sampling techniques and data.

None completed.

Section 2 Reporting of Exploration Results

(Criteria listed in the preceding section also apply to this section.)

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 Conchas Prospect lies on the Investigation Permit Conchas, PI 6,930, which is 100% owned by Berkeley Minera España S.L., a wholly owned subsidiary of Berkeley Energia Limited.

 

The I.P. Conchas is currently in the second year of its third three-year term, and will expire on 22 October 2023.

 

No historical sites, wilderness or national parks are located within the Permit. The Conchas Prospect is located adjacent to the Spain-Portugal boundary and to the village of Fuentes de Oñoro.

 

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.

Tenure in the form of an Investigation Permit has been granted and is considered secure. There are no known impediments to obtaining a licence to operate in this area.

Exploration done by other parties

Acknowledgment and appraisal of exploration by other parties.

Previous exploration at Conchas was completed initially by Billiton PLC, for tin and tantalum, between 1981 to 1983. Work completed by Billiton included mapping, pit sampling, trenching and drilling.

 

Geology

Deposit type, geological setting and style of mineralisation.

The lithium, tin and tantalum mineralisation is hosted in a muscovitic leucogranite (aplopegmatite), quite differentiated, belonging to the Guarda Batholith (Vilar Formoso-Fuentes de Oñoro sector). The regional rock is some monzonitic and granodiorite granites, of calc-alkaline character and considered as late. These are two mica granites, although biotite predominates. Locally they can present andalusite as an accessory mineral, and also apatite, zircon (included in biotite), cordierite (totally pinitized, altered to muscovite), sphene and rutile (in needles in biotite).

The mineralisation occupies a surface area of about 0.77km2, that is, approximately 1.1km long by 0.7km wide. It presents a millimetric mineralization of cassiterite and columbo-tantalite distributed homogeneously throughout its surface. Lithium mineralisation is not yet known to which mineral it is associated.

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.

No drilling completed.

 

 

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.

No drilling completed.

 

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.

Not applicable.

 

 

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.

Not applicable.

 

The assumptions used for any reporting of metal equivalent values should be clearly stated.

Not applicable.

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.

Not applicable.

 

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.

Appropriate diagrams are included in the main body of this report.

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 are reported in Appendix 5 of this report.

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 meaningful and material 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).

 

Further work planned for the Conchas Prospect will include drilling focused on testing the soil sampling anomalies.

 

 

Diagrams clearly highlighting the areas of possible extensions, including the main geological interpretations and future drilling areas, provided this information is not commercially sensitive.

These are shown in the main body of this report.

 

 

Appendix 5B

Mining exploration entity or oil and gas exploration entity
quarterly cash flow report

Name of entity

Berkeley Energia Limited

ABN


Quarter ended ("current quarter")

40 052 468 569


30 June 2022

 

Consolidated statement of cash flows

Current quarter
$A'000

Year to date
(12 months)
$A'000

1.

Cash flows from operating activities

-

-

1.1

Receipts from customers

1.2

Payments for

(439)

(2,812)


(a)   exploration & evaluation


(b)   development

-

-


(c)   production

-

-


(d)   staff costs

(550)

(1,375)


(e)   administration and corporate costs

(220)

(1,017)

1.3

Dividends received (see note 3)

-

-

1.4

Interest received

4

20

1.5

Interest and other costs of finance paid

-

-

1.6

Income taxes paid

-

-

1.7

Government grants and tax incentives

-

-

1.8

Other (provide details if material)

(a) Business Development

(b) Litigation

(17)
(50)

(29)
(196)

1.9

Net cash from / (used in) operating activities

(1,272)

(5,409)


2.

Cash flows from investing activities

-

-

2.1

Payments to acquire or for:


(a)   entities


(b)   tenements

-

-


(c)   property, plant and equipment

-

-


(d)   exploration & evaluation

-

-


(e)   investments

-

-


(f)    other non-current assets

-

-

2.2

Proceeds from the disposal of:

-

-


(a)   entities


(b)   tenements

-

-


(c)   property, plant and equipment

-

-


(d)   investments

-

-


(e)   other non-current assets

-

-

2.3

Cash flows from loans to other entities

-

-

2.4

Dividends received (see note 3)

-

-

2.5

Other (provide details if material)

-

-

2.6

Net cash from / (used in) investing activities

-

-


3.

Cash flows from financing activities

-

-

3.1

Proceeds from issues of equity securities (excluding convertible debt securities)

3.2

Proceeds from issue of convertible debt securities

-

-

3.3

Proceeds from exercise of options

-

-

3.4

Transaction costs related to issues of equity securities or convertible debt securities

-

(93)

3.5

Proceeds from borrowings

-

-

3.6

Repayment of borrowings

-

-

3.7

Transaction costs related to loans and borrowings

-

-

3.8

Dividends paid

-

-

3.9

Other (provide details if material)

-

-

3.10

Net cash from / (used in) financing activities

-

(93)


4.

Net increase / (decrease) in cash and cash equivalents for the period



4.1

Cash and cash equivalents at beginning of period

75,151

79,064

4.2

Net cash from / (used in) operating activities (item 1.9 above)

(1,272)

(5,409)

4.3

Net cash from / (used in) investing activities (item 2.6 above)

-

-

4.4

Net cash from / (used in) financing activities (item 3.10 above)

-

(93)

4.5

Effect of movement in exchange rates on cash held

6,063

6,380

4.6

Cash and cash equivalents at end of period

79,942

79,942

 

5.

Reconciliation of cash and cash equivalents
at the end of the quarter (as shown in the consolidated statement of cash flows) to the related items in the accounts

Current quarter
$A'000

Previous quarter
$A'000

5.1

Bank balances

79,892

75,101

5.2

Call deposits

50

50

5.3

Bank overdrafts

-

-

5.4

Other (provide details)

-

-

5.5

Cash and cash equivalents at end of quarter (should equal item 4.6 above)

79,942

75,151

 

6.

Payments to related parties of the entity and their associates

Current quarter
$A'000

6.1

Aggregate amount of payments to related parties and their associates included in item 1

(130)

6.2

Aggregate amount of payments to related parties and their associates included in item 2

-

Note: if any amounts are shown in items 6.1 or 6.2, your quarterly activity report must include a description of, and an explanation for, such payments.

 

7.

Financing facilities
Note: the term "facility' includes all forms of financing arrangements available to the entity.

Add notes as necessary for an understanding of the sources of finance available to the entity.

Total facility amount at quarter end
$A'000


Amount drawn at quarter end
$A'000

7.1

Loan facilities

-

-

7.2

Credit standby arrangements

-

-

7.3

Other (please specify)

-

-

7.4

Total financing facilities

-

-


 


7.5

Unused financing facilities available at quarter end

-

7.6

Include in the box below a description of each facility above, including the lender, interest rate, maturity date and whether it is secured or unsecured. If any additional financing facilities have been entered into or are proposed to be entered into after quarter end, include a note providing details of those facilities as well.

Not applicable

 

8.

Estimated cash available for future operating activities

$A'000

8.1

Net cash from / (used in) operating activities (item 1.9)

(1,272)

8.2

(Payments for exploration & evaluation classified as investing activities) (item 2.1(d))

-

8.3

Total relevant outgoings (item 8.1 + item 8.2)

(1,272)

8.4

Cash and cash equivalents at quarter end (item 4.6)

79,942

8.5

Unused finance facilities available at quarter end (item 7.5)

-

8.6

Total available funding (item 8.4 + item 8.5)

79,942




8.7

Estimated quarters of funding available (item 8.6 divided by item 8.3)

>10

Note: if the entity has reported positive relevant outgoings (ie a net cash inflow) in item 8.3, answer item 8.7 as "N/A". Otherwise, a figure for the estimated quarters of funding available must be included in item 8.7.

8.8

If item 8.7 is less than 2 quarters, please provide answers to the following questions:


8.8.1     Does the entity expect that it will continue to have the current level of net operating cash flows for the time being and, if not, why not?


Answer: Not applicable


8.8.2     Has the entity taken any steps, or does it propose to take any steps, to raise further cash to fund its operations and, if so, what are those steps and how likely does it believe that they will be successful?


Answer: Not applicable


8.8.3     Does the entity expect to be able to continue its operations and to meet its business objectives and, if so, on what basis?


Answer: Not applicable


Note: where item 8.7 is less than 2 quarters, all of questions 8.8.1, 8.8.2 and 8.8.3 above must be answered.

 

Compliance statement

1        This statement has been prepared in accordance with accounting standards and policies which comply with Listing Rule 19.11A.

2        This statement gives a true and fair view of the matters disclosed.

 

Date:                29 July 2022

Authorised by:  Company Secretary

(Name of body or officer authorising release - see note 4)

Notes

1.          This quarterly cash flow report and the accompanying activity report provide a basis for informing the market about the entity's activities for the past quarter, how they have been financed and the effect this has had on its cash position. An entity that wishes to disclose additional information over and above the minimum required under the Listing Rules is encouraged to do so.

2.          If this quarterly cash flow report has been prepared in accordance with Australian Accounting Standards, the definitions in, and provisions of, AASB 6: Exploration for and Evaluation of Mineral Resources and AASB 107: Statement of Cash Flows apply to this report. If this quarterly cash flow report has been prepared in accordance with other accounting standards agreed by ASX pursuant to Listing Rule 19.11A, the corresponding equivalent standards apply to this report.

3.          Dividends received may be classified either as cash flows from operating activities or cash flows from investing activities, depending on the accounting policy of the entity.

4.          If this report has been authorised for release to the market by your board of directors, you can insert here: "By the board". If it has been authorised for release to the market by a committee of your board of directors, you can insert here: "By the [name of board committee - eg Audit and Risk Committee]". If it has been authorised for release to the market by a disclosure committee, you can insert here: "By the Disclosure Committee".

5.          If this report has been authorised for release to the market by your board of directors and you wish to hold yourself out as complying with recommendation 4.2 of the ASX Corporate Governance Council's Corporate Governance Principles and Recommendations, the board should have received a declaration from its CEO and CFO that, in their opinion, the financial records of the entity have been properly maintained, that this report complies with the appropriate accounting standards and gives a true and fair view of the cash flows of the entity, and that their opinion has been formed on the basis of a sound system of risk management and internal control which is operating effectively.

 

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