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ODM Heavy Mineral Concentration and grain separation grain counts [#1]



ODM Heavy Mineral Concentration and grain separation (standard NGR procedure). Samples are sieved and separated using methylene iodide.

General Methodology:

The bulk sample was weighed on receipt at the laboratory1. The weight is typically about 15 kg. A 500 gram sample was removed and archived2. The remaining sample3 was wet-sieved, to remove the size fraction greater than 2 mm, which was archived4. The size fraction below 2 mm5 was separated using a Deister Diagonal-Deck Concentrating Table, model no. 15S, with a deck cover and riffles custom-built by ODM. The silt-sized gold grains were cleanly separated from the other material at this stage, by virtue of their size and density. If the sample contained more than 5-10 gold grains, it was re-tabled, to ensure a more complete recovery of the gold grains.  The table reject was re-tabled to ensure a more complete recovery of kimberlite indicator minerals (KIMs). The gold grains were counted and classified according to angularity, and then added back into the table concentrate. The light fraction from the table separation was stored6.

[The table concentrate was NOT sieved to remove the fraction below 0.25 mm, suitable for geochemical analysis7.]  The entire table concentrate from both tabling runs was separated in methylene iodide diluted with acetone to S.G. 3.20 to recover heavy minerals. The light fraction was stored8. A hand-held magnet was used to separate the ferromagnetic fraction from the heavy fraction9. The non-ferromagnetic fraction10 was sieved to remove the <0.25mm fraction, for geochemical analysis11, thus leaving any natural oxidation in the sample for analysis. The >0.25 mm fraction was washed with oxalic acid (C2H2O4), to remove any oxidized coatings). The sample was sieved again and the washed-off material was stored12. The remaining material was sieved into three size fractions (0.25-0.5 mm, 0.5-1.0mm and 1.0-2.0 mm) 13,14,15. The 0.25-0.5 mm size fraction was then separated using a high intensity lift-type induced roll separator (Carpco Model MLH (13) 111-5). The strongly paramagnetic fraction was removed first (current set to 0.6 Amp) 16, then the moderately paramagnetic fraction (0.8 Amp) 17, and finally the weakly paramagnetic fraction (1.0 Amp) 18, leaving behind the non-paramagnetic fraction19. The different paramagnetic fractions were visually inspected, and major mineralogical components (>15%) were identified for the strongly paramagnetic and non-paramagnetic fractions. These were recorded as the “input assemblage” for indicator mineral identification.

 

Sample List:

1. Bulk Received

2. Character sample

3. Table Split

4. Oversize fraction (>2 mm clasts)

5. Table Feed

6. Light fraction (table)

7. < 0.25 mm fraction (pre heavy liquid)

8. Light fraction (heavy liquid)

9. Ferromagnetic fraction

10. Non-ferromagnetic fraction

11. < 0.25 mm fraction (post heavy liquid)

12. < 0.25 mm fraction (wash)

13. 0.25-0.5 mm fraction

14. 0.5-1.0 mm fraction

15. 1.0-2.0 mm fraction

16. < 0.6 Amp fraction

17. 0.6-0.8 Amp fraction

18. 0.8-1.0 Amp fraction

19. >1.0 Amp fraction

 

Instrument: unstated

Sample material: solid

Sample weight: unstated


Analytical Technique:

Hierarchical classification

Technique >> Physical techniques >> Mineral grain separation

Children

None


Analytical Decomposition:

Hierarchical classification

Decomposition >> None

Children

None


Analytical Methods:

IndexMethod OrderMethod IDQuantityDetection Limit
1  6001     Wt_BulkRec 
2  6003     Wt_TblSplt 
3  6044     Wt_OvrSize 
4  6046     Wt_TblFeed 
5  6047     Wt_TblConc 
6  6048     Wt_MI_Lght_1 
7  6054     Wt_MI_Hvy_FM 
8  6050     Wt_MIHvyNFM_Tot_1 
9  6051     Wt_MIHvyNFM_lt25_1 
10  10  6052     Wt_MIHvyNFM_25_50 
11  11  6053     Wt_MIHvyNFM_50_100 
12  12  6178     Wt_MIHvyNFM100_200 

Associated Analytical Packages:

IndexPackage IDPackage Name
1  230     ODM HMC processing and Indicator Mineral Identification
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