Many small podiform chromitite deposits occur within two alpine-type serpentinite belts (of uncertain age) in southern NSW. Most of these deposits are enclosed in massive serpentinised chromite-rich dunite which cross-cuts primary layering within the main harzburgite body. In the western belt, the chromitites are all Cr-rich, whereas in the eastern belt there is a spectrum from Cr-rich to highly Al-rich chromitites, all of which have a fairly complex geographic distribution. All of the chromitites are ophiolitic in character and the chemistry of both the chromitites and discrete chromite grains is reasonably constant within a deposit, but varies widely between deposits. The REE concentrations are very low and lack any systematic geographic distribution. Most of the hromitites have an opholitic PGE signature, although some exceptions do occur and this is ascribed to localised remobilisation during serpentinisation. PIXE proton probe results show that the chromite grains are enriched, relative to the serpentine fracture-fill, in Mn, Ni, Zn and Ga and depleted in As and Cu. Inclusions completely enclosed within the chromite grains include Al-rich chromite, PGE-bearing nickel sulphides, palladian gold, forsteritic olivine, pargasitic amphiboles and a member of the gedrite/anthophyllite group. PGE-bearing fracture-fill phases include millerite, heazlewoodite, polydymite, chalcopyrite, trevorite, native gold, ruthenium, palladium and Ni3Pt (?). Other fracture-fill phases include awaruite, magnetite, pentlandite, lizardite 6T, chrysotile 2M, antigorite, talc, clinochlore IIb, uvarovite garnet, diopside and ferritchromit. The chromitites were derived from a different magma than the peridotite and the present distribution of low Al, intermediate Al and high Al chromitites reflects the spatial distribution of a progressively fractionating parental magma rather than different magmatic sources. Both the trace element and REE chemistries of the chromitites yield little insight into the genesis of the chromitite pods and their distribution could reflect either an inhomogeneous distribution in the parental magma or localised remobilisation during serpentinisation. During serpentinisation, PGE within the chromities and hostrock dunites rind harzburgites were released, and precipitated within the crack seal breccia environment of the chromitites. Provided that the inclusions enclosed within the chromite grains formed in the presence of the same fluid as the chromite, this magmatic chromite and olivine forming liquid must have had a minor concentrated volatile-rich component. Subsequent serpentinisation of the chromitites was responsbile for the localised remobilisation of metals, PGE. S and the REE.
