Final high-grade intersections at Longonjo

RNS Number : 9872U
Pensana Rare Earths PLC
04 August 2020
 

 

4 August 2020

 

 

 

Final drill results include further high-grade intersections in fresh rock below pit design

 

Pensana Rare Earths Plc (LSE: PRE, ASX: PM8) is pleased to report the final assay results from the last 86 holes of the 8,000 metre drill programme completed at the Longonjo NdPr Project in Angola.

 

The programme is in support of a Bankable Feasibility Study which is due to be reported in mid-October.

 

The latest results confirm the continuity of the weathered zone mineralisation from surface and also outline a wide area of mineralisation in fresh rock immediately below the current pit design that could add an extra dimension to the project beyond the initial mine life .

 

· Initial Mine Plan : Latest and final results continue to confirm the continuity of high grade rare earth mineralisation from surface in the weathered zone. The Company expects to upgrade substantial amounts of Inferred mineralisation to higher categories, supporting an extended mine life.

 

· Fresh rock mineralisation - adding a whole new dimension to the project: Wide, continuous high-grade intersections grading 2% to 4% REO have been returned from the fresh rock immediately below the weathered zone. The mineralisation remains open below the 80 metre drill depth and to the north and west. The reported grades and potential size of the further mineralisation are very encouraging and whilst not currently included in the current Bankable Feasibility Studies work has commenced on including this mineralisation in the overall development of the project.

 

· New Mineral Resource estimate: Work has commenced on an updated Mineral Resource estimate to be reported in September 2020.

 

 

Intersection highlights from the new drill results include:

 

Weathered Zone:

 

Drill hole   Intersection*

LRC295:  18 metres at 7.93% REO including 1.50% NdPr from surface

LRC298:  22 metres at 6.69% REO including 1.30% NdPr from surface

LRC310:  22 metres at 5.61% REO including 1.11% NdPr from surface

LRC344:   14 metres at 5.37% REO including 1.01% NdPr from surface

*NdPr = neodymium - praseodymium oxide. REO = total rare earth oxides. Intersections reported at a +0.4% NdPr lower grade cut off. See Table 1 for details of all new results, including wider intersections at a +0.2% NdPr cut

 

 

Fresh Rock:

 

Drill hole   Intersection

LRC274:    18 metres at 4.40% REO including 0.86% NdPr from 44 metres and

                    10 metres at 3.90% REO including 0.76% NdPr from 66 metres

LRC293:   24 metres at 3.64% REO including 0.60% NdPr from 28 metres and

   8 metres at 4.45% REO including 0.79% NdPr from 58 metres

LRC289: 14 metres at 3.23% REO including 0.64% NdPr from 18 metres and

 20 metres at 3.46% REO including 0.68% NdPr from 60 metres to end of hole

*NdPr = neodymium - praseodymium oxide. REO = total rare earth oxides. Intersections reported at a +0.4% NdPr lower grade cut off. See Table 1 for details of all new results, including wider intersections at a +0.2% NdPr cut

 

 

Executive Director & COO Dave Hammond commented:

 

"These final results have further highlighted the world-class opportunity at the Longonjo Project. The drilling continues to prove the continuity of the weathered mineralisation, returning significant grades from surface outside of our current mine plan. We expect these infill drilling results will allow us to upgrade the existing resource categories and extend the mine life.

Further drill testing of the fresh rock zone, which is not in the current mine plan, has also exceeded expectations. With many holes ending in mineralisation at eighty metres depth, identifying several open positions, the potential for a sizeable deposit of this second style of mineralisation is an exciting possibility.

All assay results have now been received, and SRK Consulting has commenced the estimation process. We look forward to reporting a new Mineral Resource estimate in September. "

 

Authorised by the Board of Pensana Rare Earths Plc

 

 

For further information:

 

Pensana Rare Earths Plc

 

Website:

Paul Atherley Chairman / Tim George, CEO

www.pensana .co.uk

contact@pensana.co.uk

Buchanan (UK Financial PR)

Bobby Morse/ Augustine Chipungu /James Husband

+44 (0) 207 466 5000

pensana@buchanan.uk.com

 

 

Technical Report

Final assay results have been received from the ~8,000 metre infill and extension reverse circulation drilling programme completed in support of Bankable Feasibility Studies (BFS) for Longonjo. The Company completed the drilling with the aim of supporting an extended mine life based on the near surface weathered zone mineralisation.

The receipt of these final assay results has allowed work on new Mineral Resource estimate for Longonjo to commence with SRK Consulting.

The new intersections are from 86 drill holes for 3,462 metres from infill drilling in the area of planned first mining, and also to the south east and north east, in areas of currently Inferred category mineralisation. Some holes were also extended to provide the first systematic test of mineralisation in the fresh rock.

See ASX announcement 15 November 2019 for Mineral Resource estimate and PFS mine plan details. All material assumptions and technical parameters underpinning the estimates continue to apply and have not materially changed.

 

The drill spacing in the majority of the project is now closed to 50 x 100 metres or closer, which is expected to support the upgrade of Inferred to Indicated and thereby support an extended mine life as the majority of the Inferred mineralisation was excluded from the PFS mine plan.

 

 

Infill and fresh rock drilling

Additional high grade intersections from the area of proposed first mining continue to demonstrate the continuity of the weathered mineralisation from surface. The 50 x 50 metre hole spacing is expected to provide the detailed data required to support an upgrade of the current Indicated to a Measured mineral resource.

 

Highlights of the numerous new high grade weathered zone intersections from surface include:

 

Drill hole  Intersection*

LRC289:  16 metres at 5.08% REO including 1.00% NdPr from surface

LRC295:  18 metres at 7.93% REO including 1.50% NdPr from surface

LRC298:  22 metres at 6.69% REO including 1.30% NdPr from surface

LRC303:  16 metres at 5.05% REO including 0.91% NdPr from surface

LRC310:  22 metres at 5.61% REO including 1.11% NdPr from surface

LRC316:  10 metres at 5.11% REO including 0.99% NdPr from surface

LRC344:  14 metres at 5.37% REO including 1.01% NdPr from surface

*NdPr = neodymium - praseodymium oxide. REO = total rare earth oxides. Intersections reported at a +0.4% NdPr lower grade cut off. Refer appendix- Table 1 for details of all new results, including wider intersections at a +0.2% NdPr cut

Holes were extended through the weathered zone to 80 metres depth to test a 450 x 300 metre area of potential fresh rock mineralisation at a 50 x 100 metre hole spacing. This provided the first systematic test of the fresh rock potential. Fresh rock mineralisation is excluded from the current BFS studies. The drilling identified thick continuous zones of +0.2% NdPr mineralisation (see Table 1) hosted within unweathered carbonatite breccia and including higher grade zones at a 0.4% NdPr grade cut:

 

Drill hole  Intersection*

LRC274:  18 metres at 4.40% REO including 0.86% NdPr from 44 metres and

    10 metres at 3.90% REO including 0.76% NdPr from 66 metres

LRC277:  10 metres at 3.60% REO including 0.90% NdPr from 70 metres to end of hole

LRC278:  10 metres at 4.65% REO including 0.77% NdPr from 68 metres to end of hole

LRC289:  14 metres at 3.23% REO including 0.64% NdPr from 18 metres and

    20 metres at 3.46% REO including 0.68% NdPr from 60 metres to end of hole

LRC293:  24 metres at 3.64% REO including 0.60% NdPr from 28 metres and

    8 metres at 4.45% REO including 0.79% NdPr from 58 metres

LRC301:  6 metres at 3.26% REO including 0.60% NdPr from 28 metres and

    12 metres at 3.73% REO including 0.63% NdPr from 38 metres

* Intersections reported at a +0.4% NdPr lower grade cut off. Refer Appendix- Table 1 for details of all new results, including wider intersections at a +0.2% NdPr cut.

 

With fresh rock hosted mineralisation in the 2 to +4% REO range open at depth and in many directions, the potential for widespread fresh rock hosted mineralisation is substantial.

 

The Company has commenced metallurgical test work to evaluate the processing of this second style of mineralisation which, if successful, could add substantially to the mine life of the initial weathered zone - based project.

 

North east margin

Additional intersections received from the north east margin of the carbonatite add to recent results in defining a consistent zone of deep weathering containing NdPr enriched rare earth mineralisation.

 

NdPr to REO ratios are higher than usual in this area, with NdPr, the projects main value driver, comprising over 30% of total REO compared to the more typical 21%.

 

The 400m long zone of deeply weathered carbonatite hosted mineralisation is 200 metres wide along the contact with the fenite. Mineralisation remains open to the north and south.

 

South East

Eight vertical holes were completed to test the continuity of mineralisation within thick transported gravels and deeply weathered carbonatite beneath. Previous and new intersections in this south east area of the project show mineralisation to continue over a 400 strike length where it remains open to the south west and north east.

 

In summary, the ~8,000 metre drilling programme completed at Longonjo from November 2019 to March 2020 has been successful in:

· demonstrating the continuity of mineralisation in the weathered zone

o to support the upgrade of Inferred to Indicated category, and thereby supporting an extended mine life

o and to upgrade Indicated to Measured in the area of proposed first mining

· proving extensions to weathered zone mineralisation in some areas

· identifying thick zones of primary mineralisation within fresh bedrock immediately beneath the weathered zone

The plan below provides an overview of the maximum NdPr% grade distribution from all drill holes within the weathered zone. The extent of the November 2019 Mineral Resource block model is shown in blue. The extensive areas of consistent high grade mineralisation (green, red and purple) both within and outside of the PFS 9 year pit illustrate the potential to extend the mine in many areas on successful completion of the Bankable Feasibility technical programmes currently in progress.

 

With all assay results now received, SRK Consulting have commenced work on a revised Mineral Resource estimate for Longonjo that will incorporate the new data from the ~8,000 metre drilling programme.

The new Mineral Resource estimate is on track for completion in September 2020 and will form the basis of the BFS mine plan.

 

Visual representations of the drill results can be found under the following link: https://pensana.co.uk/index.php/en/investors-3/asx-announcements 

 

Competent Persons Statement

The information in this report that relates to Geology, Data Quality and Exploration results is based on information compiled and/or reviewed by David Hammond, who is a Member of The Australasian Institute of Mining and Metallurgy. David Hammond is the Chief Operating Officer and a Director of the Company. He has sufficient experience which is relevant to the style of mineralisation and type of deposit under consideration and the activity which he is undertaking to qualify as a Competent Person in terms of the 2012 Edition of the Australian Code for the Reporting of Exploration Results, Mineral Resources and Ore Reserves. David Hammond consents to the inclusion in the report of the matters based on his information in the form and contest in which it appears.

The information in this statement that relates to the 2019 Mineral Resource estimates is based on work done by Rodney Brown of SRK Consulting (Australasia) Pty Ltd. Rodney Brown is a member of The Australasian Institute of Mining and Metallurgy and has sufficient experience that is relevant to the style of mineralisation and type of deposit under consideration, and to the activity he is undertaking, to qualify as a Competent Person in terms of The Australasian Code for Reporting of Exploration Results, Mineral Resources and Ore Reserves (JORC Code 2012 edition).

The Company confirms that it is not aware of any new information or data that materially affects the information included in the above original market announcements. The Company confirms that the form and context in which the Competent Person's findings are presented have not been materially modified from the original market announcement.

 

This announcement contains inside information for the purposes of Article 7 of Regulation (EU) 596/2014
 

 

Appendix

Table 1: Longonjo NdPr Project, RC drill intersections at least 4m thick and ≥0.20% NdPr lower grade cut. Intersections > 0.40% NdPr lower grade cut shown in bold italics

Hole ID

East

North

RL

Hole Depth (m)

From (m)

To (m)

Interval (m)

REO %

NdPr %

LRC274

524,249

8,571,054

1,592

80

(incl.

and

and

0

0

44

66

80

28

62

76

80eoh

28

18

10

3.49

4.40

4.19

3.92

0.68

0.86

0.79

0.76)

LRC277

524,202

8,571,150

1,602

80

(incl.

and

and

and

0

0

32

52

70

80

16

38

62

80

80eoh

16

6

10

10eoh

2.26

3.05

2.37

2.47

3.60

0.50

0.71

0.46

0.52

0.77)

LRC278

524,150

8,571,053

1,596

80

 

0

68

12

78

12

10

4.08

4.65

0.73

0.90

LRC279

524,149

8,571,152

1,605

80

(incl.

and

 

(incl.

0

0

56

68

72

62

54

60

80

76

62

54

4

12eoh

4

3.95

4.26

2.15

2.23

4.02

0.79

0.85

0.43)

0.47

0.80)

LRC280

524,099

8,571,054

1,599

80

(incl.

and

 

0

0

18

48

42

14

22

56

42

14

4

8

2.90

4.43

3.42

1.52

0.51

0.79

0.56)

0.31

LRC281

524,099

8,571,151

1,608

80

(incl.

 

(incl.

and

 

0

0

12

16

32

72

8

6

50

30

42

76

8

6

38

14

10

4

3.02

3.56

2.22

2.78

2.23

1.28

0.65

0.76)

0.47

0.58

0.43)

0.29

LRC289

524,238

8,571,349

1,625

80

(incl.

and

and

0

0

18

60

80

16

32

80

80eoh

16

14

20eoh

3.03

5.08

3.23

3.46

0.61

1.00

0.64

0.68)

LRC290

524,193

8,571,252

1,614

80

 

(incl.

and

and

0

22

26

52

68

18

80

34

66

78

18

58

8

14

10

3.44

2.13

2.23

2.29

3.49

0.84

0.46

0.50

0.50

0.67)

LRC291

524,187

8,571,353

1,629

80

(incl.

and

and

and

0

0

52

70

76

80

46

56

74

80

80eoh

46

4

4

4eoh

2.80

3.40

2.05

2.70

3.01

0.56

0.67

0.42

0.53

0.59)

LRC292

524,140

8,571,250

1,617

80

(incl.

and

and

and

0

0

24

30

64

80

22

28

36

78

80eoh

22

4

6

14

2.40

2.81

2.58

2.74

3.17

0.50

0.64

0.51

0.54

0.59)

LRC293

524,138

8,571,344

1,630

80

(incl.

and

and

and

0

0

28

58

72

80

24

52

66

80

80eoh

24

24

8

8eoh

3.42

4.30

3.64

4.45

2.76

0.67

1.01

0.60

0.79

0.51)

LRC294

524,249

8,570,950

1,585

85

(incl.

and

and

0

0

38

48

58

26

44

56

58

26

6

8

3.19

4.90

2.60

2.67

0.65

1.00

0.43

0.59)

LRC295

524,149

8,570,951

1,588

85

(incl.

 

(incl.

0

0

52

64

46

18

82

78

46

18

30

14

4.29

7.93

2.09

2.70

0.83

1.50)

0.42

0.54)

LRC296

524,300

8,570,950

1,583

85

(incl.

and

0

0

30

52

22

46

52

22

16

2.55

3.47

2.55

0.52

0.70

0.52)

LRC297

524,099

8,570,951

1,590

30

2

30

28eoh

4.46

0.92

LRC298

524,045

8,570,951

1,591

30

(incl.

0

0

28

22

28

22

5.55

6.69

1.08

1.30)

LRC299

524,349

8,570,949

1,581

39

(incl.

and

 

0

0

14

34

32

8

30

38

32

8

16

4

1.94

3.22

1.79

1.13

0.50

0.73

0.51)

0.28

LRC300

523,997

8,570,950

1,591

32

(incl.

and

0

0

24

30

16

28

30

16

4

2.75

3.80

2.08

0.57

0.76

0.53)

LRC301

524,200

8,570,950

1,587

85

(incl.

and

and

 

 

 

0

0

28

38

54

68

82

52

26

34

50

66

78

85

52

26

6

12

12

10

3eoh

3.37

3.93

3.26

3.73

1.46

1.25

1.61

0.63

0.77

0.60

0.63)

0.28

0.24

0.29

LRC302

523,950

8,570,951

1,589

22

(incl.

0

0

8

6

8

6

2.36

2.79

0.51

0.61)

LRC303

523,843

8,570,951

1,578

27

(incl.

0

0

27

16

27eoh

16

3.56

5.05

0.65

0.91)

LRC304

523,790

8,570,951

1,572

29

(incl.

 

0

0

20

14

12

28

14

12

8

3.85

4.35

1.29

0.88

0.98)

0.32

LRC305

524,051

8,570,801

1,586

39

(incl.

and

0

0

8

28

4

22

28

4

14

2.31

2.09

3.27

0.56

0.53

0.80)

LRC306

523,740

8,570,951

1,566

25

 

(incl.

0

16

16

12

25

20

12

9eoh

4

2.10

1.90

3.11

0.46

0.35

0.57)

LRC307

523,801

8,570,757

1,568

27

(incl.

and

0

0

10

26

6

16

26

6

6

2.12

2.36

3.04

0.49

0.63

0.67)

LRC308

523,699

8,570,860

1,556

20

(incl.

0

0

20

4

20eoh

4

2.33

3.34

0.51

0.68)

LRC310

524,172

8,570,750

1,581

42

(incl.

0

0

24

22

24

22

5.30

5.61

1.04

1.11)

LRC311

523,750

8,570,859

1,563

32

(incl.

0

0

24

10

24

10

2.55

4.22

0.56

0.93)

LRC312

524,226

8,570,750

1,578

36

(incl.

and

0

0

26

36

14

36

36eoh

14

10eoh

2.94

4.59

2.21

0.58

0.89

0.45)

LRC313

523,799

8,570,856

1,568

36

(incl.

and

and

0

0

14

24

36

10

20

32

36eoh

10

6

8

2.47

2.61

4.26

2.62

0.60

0.56

1.10

0.69)

LRC314

524,274

8,570,750

1,575

27

(incl.

and

0

0

10

24

6

20

24

6

10

2.68

3.54

3.36

0.58

0.77

0.71)

LRC315

523,850

8,570,852

1,573

30

(incl.

0

0

28

18

28

18

2.59

3.29

0.65

0.84)

LRC316

524,325

8,570,750

1,573

19

(incl.

0

0

19

10

19eoh

10

3.55

5.11

0.69

0.99)

LRC317

524,374

8,570,750

1,571

42

(incl.

 

0

0

36

8

4

40

8

4

4

2.82

4.25

2.92

0.59

0.90)

0.56

LRC318

523,900

8,570,854

1,577

30

0

22

16

30

16

8eoh

2.04

1.40

0.46

0.32

LRC319

524,434

8,570,750

1,568

26

(incl.

0

0

8

6

8

6

2.79

3.28

0.58

0.68)

LRC320

523,951

8,570,852

1,582

25

(incl.

0

0

24

22

24

22

3.05

3.16

0.62

0.64)

LRC321

524,475

8,570,752

1,566

29

(incl.

and

0

0

24

29

18

29

29eoh

18

5eoh

3.50

4.15

3.77

0.60

0.74

0.54)

LRC322

524,001

8,570,850

1,585

24

(incl.

0

4

18

8

18

4

2.08

2.88

0.41

0.62)

LRC323

524,526

8,570,752

1,564

20

0

4

4

2.07

0.42

LRC324

524,051

8,570,851

1,587

26

(incl.

and

and

0

0

6

14

26

4

12

18

26eoh

4

6

4

1.90

2.69

2.46

2.13

0.42

0.60

0.54

0.47)

LRC325

524,749

8,570,499

1,547

39

(incl.

 

0

0

28

12

10

34

12

10

6

2.06

2.12

1.37

0.50

0.52)

0.47)

LRC326

524,100

8,570,850

1,585

44

(incl.

and

0

0

22

42

20

32

42

20

10

3.14

3.84

3.95

0.71

0.83

0.97)

LRC327

524,151

8,570,849

1,583

46

(incl.

and

0

0

22

46

20

28

46eoh

20

6

2.26

2.94

2.30

0.51

0.65

0.55)

LRC328

524,548

8,570,500

1,548

40

(incl.

and

 

0

0

22

32

30

10

30

36

30

10

8

4

2.05

2.80

2.24

1.90

0.48

0.57

0.60)

0.52

LRC329

524,200

8,570,849

1,581

44

(incl.

and

0

0

26

44

14

30

44eoh

14

4

1.81

2.88

1.55

0.42

0.66

0.42)

LRC330

524,649

8,570,500

1,548

55

(incl.

 

(incl.

0

0

30

32

10

8

54

50

10

8

24

18

2.25

2.57

1.75

2.02

0.52

0.57)

0.54

0.63)

LRC331

524,249

8,570,849

1,580

30

(incl.

0

0

24

10

24

10

2.33

3.81

0.53

0.87)

LRC332

524,651

8,570,400

1,543

37

(incl.

0

14

20

18

20

4

1.51

2.08

0.40

0.60)

LRC333

524,300

8,570,851

1,578

28

(incl.

0

0

28

12

28eoh

12

2.85

4.92

0.61

1.04)

LRC334

524,350

8,570,850

1,576

26

(incl.

and

0

0

14

24

8

22

24

8

8

2.39

3.21

2.54

0.52

0.70

0.54)

LRC335

524,399

8,570,850

1,574

44

(incl.

0

0

38

28

38

28

2.88

3.41

0.62

0.75)

LRC336

524,450

8,570,850

1,572

45

(incl.

0

0

30

6

4

45

6

4

15eoh

2.28

2.94

1.81

0.48

0.60)

0.35

LRC337

524,511

8,571,547

1,729

36

(incl.

0

2

12

6

12

4

1.56

1.85

0.35

0.45)

LRC338

524,559

8,570,398

1,543

24

(incl.

0

0

18

16

18

16

2.55

2.71

0.53

0.56)

LRC339

524,597

8,570,302

1,538

36

0

12

28

6

26

34

6

14

6

1.13

0.97

0.68

0.26

0.28

0.21

LRC340

524,500

8,571,700

1,725

70

(incl.

and

and

and

0

0

10

24

36

70

8

18

28

64

70eoh

8

8

4

28

1.62

1.76

1.70

1.57

2.01

0.43

0.47

0.48

0.49

0.52)

LRC341

524,498

8,570,301

1,537

20

(incl.

0

0

10

8

10

8

2.67

3.03

0.54

0.60)

LRC342

524,398

8,570,301

1,537

24

0

4

4

1.53

0.27

LRC343

524,449

8,571,700

1,713

83

(incl.

and

0

0

24

74

14

28

74

14

4

1.47

1.51

1.53

0.38

0.42

0.44)

LRC344

524,590

8,571,237

1,611

20

(incl.

0

0

20

14

20eoh

14

4.49

5.37

0.85

1.01)

LRC345

524,639

8,571,243

1,611

12

(incl.

0

0

10

4

10

4

2.08

3.41

0.42

0.69)

LRC346

524,700

8,571,178

1,591

24

NSI

LRC347

524,649

8,571,140

1,588

23

0

14

14

4.01

0.75

LRC348

524,351

8,571,898

1,690

40

(incl.

0

0

19

10

19

10

2.02

2.88

0.48

0.70)

LRC349

524,605

8,571,141

1,590

25

(incl.

and

0

0

10

24

6

14

24

6

4

2.01

3.94

1.86

0.50

0.96

0.49)

LRC350

524,549

8,571,140

1,592

26

0

12

12

2.22

0.55

LRC351

524,335

8,571,957

1,683

33

NSI

LRC352

524,497

8,571,150

1,594

24

0

6

6

1.53

0.38

LRC353

524,449

8,571,150

1,594

20

(incl.

0

0

18

10

18

10

2.30

3.15

0.52

0.71)

LRC354

524,139

8,571,398

1,642

30

0

30

30eoh

2.92

0.68

LRC355

524,598

8,571,050

1,579

24

(incl.

and

0

0

12

18

10

16

18

10

4

2.73

3.62

2.42

0.66

0.89

0.55)

LRC356

524,549

8,571,049

1,581

30

(incl.

0

0

10

8

10

8

3.66

4.18

0.95

1.09)

LRC357

524,044

8,571,250

1,623

18

(incl.

0

0

18

8

18eoh

8

2.04

2.84

0.49

0.67)

LRC358

524,498

8,571,051

1,582

33

 

0

14

4

18

4

4

2.17

2.22

0.48

0.46

LRC359

524,091

8,571,250

1,620

34

0

34

34eoh

3.66

0.76

LRC360

524,041

8,571,206

1,615

36

(incl.

0

0

32

26

32

26

3.51

3.86

0.74

0.83)

LRC361

523,576

8,571,302

1,612

27

(incl.

0

0

27

12

27eoh

12

2.45

3.72

0.49

0.75)

LRC362

524,405

8,570,953

1,580

36

(incl.

and

and

0

0

10

24

36

6

14

30

36eoh

6

4

6

2.03

3.69

1.98

3.48

0.46

0.77

0.48

0.79)

LRC363

524,691

8,571,235

1,606

20

(incl.

0

6

12

12

12

6

2.20

3.53

0.43

0.65)

LRC364

524,449

8,570,950

1,577

26

(incl.

 

0

0

14

10

6

20

10

6

6

2.62

3.32

3.55

0.51

0.67)

0.62

LRC365

524,500

8,570,949

1,575

29

(incl.

 

0

0

26

12

4

29

12

4

3eoh

1.76

2.71

1.39

0.37

0.60)

0.29

LRC366

524,555

8,570,951

1,572

27

(incl.

0

0

10

4

10

4

1.74

2.76

0.37

0.58)

LRC367

524,498

8,570,854

1,570

27

(incl.

0

0

22

20

22

20

3.05

3.23

0.57

0.60)

LRC368

524,598

8,570,948

1,571

26

(incl.

0

0

6

4

6

4

2.10

2.66

0.45

0.55)

LRC369

524,547

8,570,854

1,567

32

(incl.

and

0

0

10

26

6

18

26

6

8

2.21

3.09

3.05

0.50

0.64

0.68)

           

*All holes are vertical reverse circulation. REO = Total rare earth oxide includes NdPr and is the sum of La2O3, CeO2, Pr6O11, Nd2O3, Sm2O3, Eu2O3, Gd2O3, Tb4O7, Dy2O3, Ho2O3, Er2O3, Tm2O3, Yb2O3, Lu2O3, Y2O3. NdPr = neodymium + praseodymium oxide. eoh = intersection to end of hole. Co-ordinate system is WGS84 UTM Zone 33 south, rounded to nearest metre. Assays of 2m composite samples by peroxide fusion and ICP analysis, Nagrom laboratories Perth, Western Australia. Maximum of 2m internal subgrade included.

 

 

APPENDIX

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 (e.g. 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.

· All samples are from reverse circulation (RC) drilling sampled to 2m composites using a 3 tier riffle splitter to obtain approximately 4kg of sample from the whole one metre rig sample for sample preparation. Entire down hole lengths were sampled from surface to end of hole.

 

 

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

· During RC drilling the drill string is cleaned by flushing with air and the cyclone cleaned regularly.

· Sampling is carried out under Pensana QAQC protocols and as per industry best practise.

· RC sample returns are closely monitored, managed and recorded. A reference weight is used to calibrate the weighing scale.

· Samples are riffle split using a 3 tier splitter which is cleaned between every sample

 

 

· 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 (e.g. '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 (e.g. submarine nodules) may warrant disclosure of  detailed information.

· Reverse circulation drilling and a riffle splitter were used to obtain 2m samples of approximately 3 to 4kgs. Samples are prepared (dry, split, pulverise, split) to a 100g pulp for analysis at Analabs laboratories Windhoek, Namibia

· Samples are assayed at for Ca, Fe, K, Mg, Mn, P Pb, S, Si, Sr, Ti, Zn, Ce, Dy, Er, Eu, Gd, Hf, Ho, La, Lu, Nb, Nd, Pr, Sm, Ta, Tb, Th, Tm, U, Y, Yb, Al, Ba by peroxide fusion followed by ICP analysis at Nagrom laboratories, Perth, Western Australia.

· All commercial laboratories used use industry best practise procedures and QAQC checks.

· Entire hole lengths were submitted for assay.

 

 

 

 

Drilling techniques

· Drill type (e.g. core, reverse circulation, open-hole hammer, rotary air blast, auger, Bangka, sonic, etc) and details (e.g. 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).

· Reverse circulation (RC) drilling was completed using a Super rock 100 drill rig with a face sampling hammer button bit of 131mm diameter and 5 metre rods. A 131mm diameter blade RC bit was used in most holes in the weathered zone, generally for around 10 metres.

 

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.

· RC recoveries were monitored closely, recorded and assessed regularly over the drilling programme.

· Every 1m sample from the rig was weighed and recorded for moisture content. The weigh scale was calibrated frequently.

 

· RC sample weights are compared against expected weights for the drill diameter and geology.

· Drill pipes and cyclone were flushed and cleaned regularly

 

· Some short intervals 1 to 3 metres of reduced sample recovery occur in the soft weathered zone in some holes. Data analysis to date including diamond hole twins to RC holes, has not identified any relationship between recovery and grade.

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.

· RC 1m samples were geological logged by specifically trained geologists for the entire length of all holes. All relevant features such as lithology, mineralogy, weathering, structure, texture, grain-size, alteration, veining style and mineralisation were recorded in the geological log.

 

 

· All logging was quantitative.  All RC chip trays were photographed.

 

 

· All holes were logged in full 100%

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.

· RC drilling only, no core drilling results reported

 

 

· 1m rig samples were riffle split using a 3 tier splitter. All samples were dry or wet samples were sun-dried in a protected environment before sampling.

 

· The preparation of samples follows industry practice.  This involves oven drying of the full 4kg 2m composite sample, splitting to a representative 1kg sample, pulverising to 85% passing 75 micron and splitting to a 100g sample pulp.

· Field duplicates, certified reference standards and blanks were inserted at random but on average every 27 samples for each as part of Pensana QAQC protocols as per industry best practise. Laboratories also have and report internal QAQC checks including assay and preparation duplicates

· Field, preparation and assay lab duplicate results indicate no significant sampling variance

 

 

 

· The sample sizes are considered more than adequate for this disseminated style and grainsize of material sampled. Repeatability of assays is good.

Quality of assay data and laboratory tests

· The nature, quality and appropriateness of the assaying and laboratory procedures used and whether the technique is considered partial or total.

 

 

· For geophysical tools, spectrometers, handheld XRF instruments, etc, the parameters used in determining the analysis including instrument make and model, reading times, calibrations factors applied and their derivation, etc.

· Nature of quality control procedures adopted (e.g. standards, blanks, duplicates, external laboratory checks) and whether acceptable levels of accuracy (ie lack of bias) and precision have been established.

· The analysis was carried out by an accredited independent assay laboratory. 

· Samples are assayed at for Ca, Fe, K, Mg, Mn, P Pb, S, Si, Sr, Ti, Zn, Ce, Dy, Er, Eu, Gd, Hf, Ho, La, Lu, Nb, Nd, Pr, Sm, Ta, Tb, Th, Tm, U, Y, Yb, Al, Ba by peroxide fusion, hydrochloric leach and followed by ICP analysis at Nagrom laboratories, Perth, Western Australia.

· The assay technique is total.

 

· Laboratory data only. No geophysical or portable analysis tools were used to determine assay values stored in the database.

 

 

 

 

 

 

 

· Certified reference materials (CRM's) -standards and blanks - were submitted at random with the field samples on an average of 1 of each type every in 27 field samples basis, as well as the laboratory's standard QAQC procedures.

· Samples were selected periodically and screened tested to ensure pulps are pulverised to the required specifications.

· Analysis of QAQC data results indicates acceptable levels of accuracy and precision

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.

· Significant intersections have been verified by company management.

 

 

· No twins completed for the current programme. Twin diamond holes have been completed for previous RC drill programmes with no bias observed.

· Field data was logged into an Ocris logging package and uploaded to the main, secure, database in Perth once complete.  The data collection package has built in validation settings and look-up codes. All field data and assay data was verified and validated upon receipt. The database is managed by an independent and professional database manager offsite

· Data collection and entry procedures are documented and training given to all staff

· Scans of original field data sheets are stored digitally and never altered

· Digital data entry is checked and validated against original field sheets if not entered directly

· Laboratory assay data for rare earths is received in element form and converted to oxides for the reporting of rare earth results using molecular weight conversion and the oxide states factors:

La to La2O3 - 1.1728

Ce to CeO2 - 1.2284

Pr to Pr6O11 - 1.2082

Nd to Nd2O3 - 1.1664

Sm to Sm2O3 - 1.1596

Eu to Eu2O3 - 1.1579

Gd to Gd2O3 - 1.1526

Tb to Tb4O7 - 1.1762

Dy to Dy2O3 - 1.1477

Ho to Ho2O3 - 1.1455

Er to Er2O3 - 1.1435

Tm to Tm2O3 - 1.1421

Yb to Yb2O3 - 1.1387

Lu to Lu2O3 - 1.1371

Y to Y2O3 - 1.2699

· Intersection grades are reported as REO (the sum of the above oxides) and as NdPr (the sum of Nd2O3 and Pr6O11, which is included in the REO grade

Location of data points

· Accuracy and quality of surveys used to locate drill holes (collar and down-hole surveys), trenches, mine workings and other locations used in Mineral Resource estimation.

 

 

· Specification of the grid system used.

· Quality and adequacy of topographic control.

· All drill hole collar locations have been accurately surveyed by a professional surveyor using an RTK DGPS at the end of the programme.

· All new drill holes reported are vertical, with no down hole survey completed. 33 holes from the current programme previously reported are angled at -60 degrees to the south or east and were surveyed at 5m intervals using a down hole gyro tool. The collar set up was checked on every hole by measuring the angle of the mast is vertical using a spirit level clinometer.

· The grid system used is WGS84 UTM Zone 33S. All reported coordinates are referenced to this grid.

· Topography is modelled using a high precision satellite based topographic survey and surveyed drill collars fitted to the surface. An RTK DGPS survey has been completed on ground control points to ensure accuracy and precision of the satellite DTM survey.

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.

· Drill hole spacing is 50m x 50m in the central area and 100m x 50m elsewhere. Samples are 2m down hole.

· Data spacing is considered sufficient to establish geological and grade continuity of this disseminated style of NdPr and REO mineralisation and support Mineral Resource estimation.

· 1m RC drill samples were combined in the field after riffle splitting for a final 2m composite sample for submission to laboratory.

· Two metre composites are considered adequate for the resource estimation, variography studies and potential mining techniques for this style of mineralisation

 

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.

· High grade NdPr mineralisation within the central parts of the Longonjo carbonatite occurs as a thick horizontal blanket of disseminated mineralisation within weathered carbonatite averaging 20m or more in thickness and with good lateral continuity. The vertical drilling and 2m sampling is optimum for this style of mineralisation.

· Subvertical carbonatite dykes and carbonatite:country rock contacts occur on the margins of the carbonatite body, overprinted by a zone of subhorizontal weathering of variable thickness. This peripheral zone is tested by angled -600 drill holes perpendicular to strike, which are considered optimum to intersect both vertical and horizontal orientations to the mineralisation.

· No sampling bias is considered to have been introduced by the drilling orientation.

 

Sample security

· The measures taken to ensure sample security.

· Sample security is managed by the Company. After collection in the field the samples are stored at camp in locked sea containers.

· A customs officer checks and seals the samples into containers on site before transportation by the Company directly to the preparation laboratory. The preparation laboratory submits the samples to the assay laboratory by international air freight - the samples again being inspected by customs and sealed prior to despatch.

· The laboratories audit the samples on arrival and reports any discrepancies back to the Company. No such discrepancies occurred.

 

Audits or reviews

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

· SRK has completed a site visit and conducted a review of the primary and QAQC data as part of the November 2019 Mineral Resource estimation work. The database is compiled by an independent consultant and is considered by the Company to be of sufficient quality to support the results reported. In addition, from time to time, the Company carries out its own internal data audits.

 

 

 

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 security of the tenure held at the time of reporting along with any known impediments to obtaining a licence to operate in the area.

· Mining License Nº298/05/01/T.E/ANG‐MIREMPET/2020. Pensana owns an 84% holding in the Project with Ferrangol (10%), an agency of the Angolan government, and other Angolan partners (6%).

 

 

 

 

· The concession is in good standing and no known impediments exist.

 

Exploration done by other parties

· Acknowledgment and appraisal of exploration by other parties.

· Previous workers in the area include Black Fire Minerals and Cityview Corporation Ltd.

Geology

· Deposit type, geological setting and style of mineralisation.

· The Longonjo NdPr deposit occurs within the rare earth enriched Longonjo Carbonatite, a sub circular and subvertical explosive volcanic vent (diatreme) approximately 2.6km x 2.4km in diameter. Primary rocktypes include carbonatite lava and magma, extensive mixed carbonatite - fenite breccia and tuffaceous deposits. Mineralisation is disseminated in style. Particularly high grades occur within the iron rich weathered zone that extends from surface over much of the carbonatite. The higher grades in the regolith are a result of residual enrichment through dissolution of primary carbonate minerals. NdPr rare earth mineralisation also occurs within fresh rock carbonatite and carbonatite:fenite breccia beneath the weathered zone and associated with subvertical carbonatite ring dykes on the carbonatite margins.

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:

easting and northing of the drill hole collar

elevation or RL (Reduced Level - elevation above sea level in metres) of the drill hole collar

dip and azimuth of the hole

down hole length and interception depth

hole length.

· If the exclusion of this information is justified on the basis that the information is not Material and this exclusion does not detract from the understanding of the report, the Competent Person should clearly explain why this is the case.

· Refer to the Table 1 in the body of the text. All drill holes reported in the current announcement are vertical.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

· No material information was excluded.

Data aggregation methods

· In reporting Exploration Results, weighting averaging techniques, maximum and/or minimum grade truncations (e.g. cutting of high grades) and cut-off grades are usually Material and should be stated.

· Where aggregate intercepts incorporate short lengths of high grade results and longer lengths of low grade results, the procedure used for such aggregation should be stated and some typical examples of such aggregations should be shown in detail.

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

· Cut-off grade of 0.20% NdPr oxide applied in reporting of intersections and 0.40% NdPr oxide for high grade 'Highlights'. No upper grade cuts have been applied.

· Intersections are reported as length weighted averages above the specified cut-off grade.Length weighted grade averages for REO and NdPr are presented

 

 

· Intercepts may include a maximum of 2m internal dilution.

 

 

 

 

 

 

· No metal equivalent values have been used for the reporting of these exploration results.

Relationship between mineralisation widths and intercept lengths

· These relationships are particularly important in the reporting of Exploration Results.

· If the geometry of the mineralisation with respect to the drill hole angle is known, its nature should be reported.

· If it is not known and only the down hole lengths are reported, there should be a clear statement to this effect (e.g. 'down hole length, true width not known').

 

 

 

 

· Geometry of the mineralisation is a sub horizontal blanket, the drill holes are vertical. As such mineralisation is at a high angle to the drill holes.

· Drill hole intercepts reported can be considered true thicknesses in the centre of the carbonatite

 

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 plans and sections are included in this release.

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 new exploration results above the specified cut off grade are reported.

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.

· Previously reported evaluations of the NdPr mineralisation at Longonjo, including the November 2019 Mineral Resource estimate and drilling programme results are contained within ASX releases

Further work

· The nature and scale of planned further work (e.g. tests for lateral extensions or depth extensions or large-scale step-out drilling).

 

 

 

 

 

 

 

 

 

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

· The reported results are the fifth and final batch from 86 of a total 195 hole infill and extension RC drilling programme testing the shallow weathered zone and an area of underlying fresh rock mineralisation at Longonjo. Drilling is designed to provide data for a revised Mineral Resource estimate and to upgrade a significant portion of the large amount of Inferred weathered zone Mineral Resource at Longonjo to Indicated or Measured category, thereby enabling the current 9 year mine life as defined in the November 2019 Preliminary Feasibility Study to be extended. The revised Mineral Resource estimate will form part of the Bankable Feasibility Study for Longonjo.

 

 

· Appropriate diagrams accompany this release.

 

 


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