The Mineralogy of Pt-Fe alloys and phase relations in the Pt–Fe binary system-Reference-Cited by-同舟云学术

The Mineralogy of Pt-Fe alloys and phase relations in the Pt–Fe binary system

Published:2022-03-01 Issue:2 Volume:60 Page:331-339
ISSN:1499-1276
Container-title:The Canadian Mineralogist
language:en
Short-container-title:

Author:

Cabri Louis J.¹,Oberthür Thomas²,Schumann Dirk³

Affiliation:

1. 514 Queen Elizabeth Drwy, Ottawa, Ontario K1S 3N4, Canada

2. Bundesanstalt für Geowissenschaften und Rohstoffe (BGR), Stilleweg 2, D-30655 Hannover, Germany

3. Fibics Incorporated, 1431 Merivale Road, Suite 100, Lower Level, Ottawa, Ontario K2E 0B9, Canada

Abstract

ABSTRACT A revised Pt–Fe phase diagram is proposed to replace those used in the materials science literature (e.g., Okamoto 2004), and to improve the one of Cabri & Feather (1975) by adding high-temperature phase equilibria data published in the mineralogical literature. The projected solid-solution fields at room temperature in the pure Pt–Fe system lie at the following approximate compositions: for γ(Pt,Fe) from Pt to Pt0.78Fe0.22, for Pt3Fe from Pt3.04Fe0.96 to Pt2.64Fe1.36, for PtFe from Pt1.16Fe0.84 to Pt0.67Fe0.33, and for PtFe3 from Pt1.26Fe2.94 to Pt0.68Fe3.32. The phase relations and phase boundaries are discussed and evaluated for Pt-Fe alloys occurring in pristine intrusive rocks and ores as well as in eluvial and placer deposits derived from the former by physical and chemical weathering over long periods of geologic time. In spite of the variable concentrations of minor and trace elements, the natural Pt-Fe alloy minerals correlate well with phase relations in the pure Pt–Fe binary system.

Publisher

Mineralogical Association of Canada

Subject

Geochemistry and Petrology

Link

https://pubs.geoscienceworld.org/canmin/article-pdf/60/2/331/5579474/i1499-1276-60-2-331.pdf

Reference39 articles.

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