Mineral physicochemistry underlying feature‐based extraction of mineral abundance and composition from shortwave, mid and thermal infrared reflectance spectra

Abstract

Reflectance spectroscopy allows cost‐effective and rapid mineral characterisation, ad-dressing mineral exploration and mining challenges. Shortwave (SWIR), mid (MIR) and thermal (TIR) infrared reflectance spectra are collected in a wide range of environments and scales, with instrumentation ranging from spaceborne, airborne, field and drill core sensors to IR microscopy. However, interpretation of reflectance spectra is, due to the abundance of potential vibrational modes in mineral assemblages, non‐trivial and requires a thorough understanding of the potential factors contributing to the reflectance spectra. In order to close the gap between understanding min-eral‐diagnostic absorption features and efficient interpretation of reflectance spectra, an up‐to‐date overview of major vibrational modes of rock‐forming minerals in the SWIR, MIR and TIR is pro-vided. A series of scripts are proposed that allow the extraction of the relative intensity or wavelength position of single absorption and other mineral‐diagnostic features. Binary discrimination diagrams can assist in rapidly evaluating mineral assemblages, and relative abundance and chemical composition of key vector minerals, in hydrothermal ore deposits. The aim of this contribution is to make geologically relevant information more easily extractable from reflectance spectra, ena-bling the mineral resources and geoscience communities to realise the full potential of hyperspectral sensing technologies.