The composition of mackinawite

Rickard, David ORCID: https://orcid.org/0000-0002-4632-5711 2024. The composition of mackinawite. American Mineralogist 109 , pp. 401-407. 10.2138/am-2023-8943 Item availability restricted.

PDF - Accepted Post-Print Version Restricted to Repository staff only until 1 July 2024 due to copyright restrictions. Download (855kB)

Abstract

The composition of a mineral is a defining characteristic. The various compositions listed for mackinawite in current mineralogical databases and reference books, such as Fe(Ni)S and Fe1+xS, are both wrong and misleading. Statistical analyses of over 100 mackinawite compositions reported over the last 50 years show a mean composition of Me1.0S where Me = Fe + Co + Ni + Cu. Mackinawite is stoichiometric FeS. As with many sulfide minerals, Ni-, Co-, and, possibly, Cu-rich varieties occur in addition to the simple iron monosulfide. These varieties are best referred to as nickelian mackinawite, cobaltian mackinawite, and cupriferous mackinawite. The results confirm that these metals substitute for Fe in the mackinawite structure rather than being contained in the interstices between the Fe-S layers. Most compositional data on mackinawites derive from electron probe microanalyses of small grains in magmatic/hydrothermal associations. The result means that there is no dichotomy between the composition of ambient temperature synthetic mackinawite (which is supposed to be equivalent to sedimentary mackinawite) and mackinawites from higher temperature associations. The correct representation of the composition of mackinawite has implications for a wide swathe of fundamental science, including the origin of life, the genesis of magmatic ore deposits, the provenance of meteorites as well as industrial applications such as water treatment and steel corrosion. The stoichiometric formulation permits the mackinawite formula to be balanced electronically using conventional Fe and S ionic species. It also enables simple, balanced chemical equations involving mackinawite.

Item Type:	Article
Date Type:	Publication
Status:	Published
Schools:	Earth and Environmental Sciences
Publisher:	Mineralogical Society of America
ISSN:	1945-3027
Funders:	n/a
Date of First Compliant Deposit:	7 June 2023
Date of Acceptance:	30 May 2023
Last Modified:	29 Apr 2024 19:02
URI:	https://orca.cardiff.ac.uk/id/eprint/160217

Actions (repository staff only)

Edit Item