3928 XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3
Daniel, M.J., &Morley, C. (2010). Can diamonds go all
the way with HPGRs. In Colloquium: Diamonds–
Source to Use.
Fedortchouk, Y. (2019). A new approach to understanding
diamond surface features based on a review of experi-
mental and natural diamond studies. Earth-science
reviews, 193, 45–65.
Sasman, F., Deetlefs, B., &van der Westhuyzen, P. (2018).
Application of diamond size frequency distribution
and XRT technology at a large diamond producer.
Journal of the Southern African Institute of Mining
and Metallurgy, 118(1), 1–6.
Haggerty, S.E. (2019). Micro-diamonds: Proposed ori-
gins, crystal growth laws, and the underlying prin-
ciple governing resource predictions. Geochimica et
Cosmochimica Acta, 266, 184–196.
Field, J.E. (2012). The mechanical and strength properties
of diamond. Reports on Progress in Physics, 75(12),
126505.
Harris, J.W., Smit, K.V., Fedortchouk, Y., &Moore,
M. (2022). Morphology of monocrystalline dia-
mond and its inclusions. Reviews in Mineralogy and
Geochemistry, 88(1), 119–166.
Irifune, T., Kurio, A., Sakamoto, S., Inoue, T., &Sumiya,
H. (2003). Ultrahard polycrystalline diamond from
graphite. Nature, 421(6923), 599–600.
Angel, R.J., Alvaro, M., &Nestola, F. (2022).
Crystallographic methods for non-destructive charac-
terization of mineral inclusions in diamonds. Reviews
in Mineralogy and Geochemistry, 88(1), 257–305.
Harris, J.W. (1972). Black material on mineral inclu-
sions and in internal fracture planes in diamond.
Contributions to mineralogy and petrology, 35(1),
22–33.
Pavlushin, A.D., &Konogorova, D.V. (2023).
Crystallogenetic Causes of the Unique Shape of
the Matryoshka Diamond: The Effect of Capturing
a Diamond Inclusion of Twin Diamond Crystals.
Geochemistry International, 61(3), 252–264.
Titkov, S.V., Krivovichev, S.V., &Organova, N.I. (2012).
Plastic deformation of natural diamonds by twinning:
evidence from X-ray diffraction studies. Mineralogical
Magazine, 76(1), 143–149.
Little L., Mainza, A N., Becker M., &Wiese J.G. (2016).
Using mineralogical and particle shape analysis to
investigate enhanced mineral liberation through phase
boundary fracture. Powder Technology, 301, 794–804.
Hatch, F. &Corstorphine, G.S. (1905). The Cullinan
Diamond. South African Journal of Geology, 8(1),
26–27.
Pearson, D.G., Woodhead, J., &Janney, P.E. (2019).
Kimberlites as geochemical probes of Earth’s mantle.
Elements: An International Magazine of Mineralogy,
Geochemistry, and Petrology, 15(6), 387–392.
Smith, B.S., Nowicki, T.E., Russell, J.K., Webb, K.,
Mitchell, R.H., Hetman, C., &vA Robey, J. (2018).
A glossary of kimberlite and related terms. Scott-Smith
Petrology Incorporated.
Daniel, M.J., &Morley, C. (2010). Can diamonds go all
the way with HPGRs. In Colloquium: Diamonds–
Source to Use.
Fedortchouk, Y. (2019). A new approach to understanding
diamond surface features based on a review of experi-
mental and natural diamond studies. Earth-science
reviews, 193, 45–65.
Sasman, F., Deetlefs, B., &van der Westhuyzen, P. (2018).
Application of diamond size frequency distribution
and XRT technology at a large diamond producer.
Journal of the Southern African Institute of Mining
and Metallurgy, 118(1), 1–6.
Haggerty, S.E. (2019). Micro-diamonds: Proposed ori-
gins, crystal growth laws, and the underlying prin-
ciple governing resource predictions. Geochimica et
Cosmochimica Acta, 266, 184–196.
Field, J.E. (2012). The mechanical and strength properties
of diamond. Reports on Progress in Physics, 75(12),
126505.
Harris, J.W., Smit, K.V., Fedortchouk, Y., &Moore,
M. (2022). Morphology of monocrystalline dia-
mond and its inclusions. Reviews in Mineralogy and
Geochemistry, 88(1), 119–166.
Irifune, T., Kurio, A., Sakamoto, S., Inoue, T., &Sumiya,
H. (2003). Ultrahard polycrystalline diamond from
graphite. Nature, 421(6923), 599–600.
Angel, R.J., Alvaro, M., &Nestola, F. (2022).
Crystallographic methods for non-destructive charac-
terization of mineral inclusions in diamonds. Reviews
in Mineralogy and Geochemistry, 88(1), 257–305.
Harris, J.W. (1972). Black material on mineral inclu-
sions and in internal fracture planes in diamond.
Contributions to mineralogy and petrology, 35(1),
22–33.
Pavlushin, A.D., &Konogorova, D.V. (2023).
Crystallogenetic Causes of the Unique Shape of
the Matryoshka Diamond: The Effect of Capturing
a Diamond Inclusion of Twin Diamond Crystals.
Geochemistry International, 61(3), 252–264.
Titkov, S.V., Krivovichev, S.V., &Organova, N.I. (2012).
Plastic deformation of natural diamonds by twinning:
evidence from X-ray diffraction studies. Mineralogical
Magazine, 76(1), 143–149.
Little L., Mainza, A N., Becker M., &Wiese J.G. (2016).
Using mineralogical and particle shape analysis to
investigate enhanced mineral liberation through phase
boundary fracture. Powder Technology, 301, 794–804.
Hatch, F. &Corstorphine, G.S. (1905). The Cullinan
Diamond. South African Journal of Geology, 8(1),
26–27.
Pearson, D.G., Woodhead, J., &Janney, P.E. (2019).
Kimberlites as geochemical probes of Earth’s mantle.
Elements: An International Magazine of Mineralogy,
Geochemistry, and Petrology, 15(6), 387–392.
Smith, B.S., Nowicki, T.E., Russell, J.K., Webb, K.,
Mitchell, R.H., Hetman, C., &vA Robey, J. (2018).
A glossary of kimberlite and related terms. Scott-Smith
Petrology Incorporated.