Abstract
While multispectral images have been in regular use since the 1970s, the
widespread use of hyperspectral images is a relatively recent trend.
This technology comprises remote measurement of specific chemical and
physical properties of surface materials through imaging spectroscopy.
Regional geological mapping and mineral exploration are among the main
applications that may benefit from hyperspectral technology. Minerals
and rocks exhibit diagnostic spectral features throughout the
electromagnetic spectrum that allow their chemical composition and
relative abundance to be mapped. Most studies using hyperspectral data
for geological applications have concerned areas with arid to semi-arid
climates, and using airborne data collection. Other studies have
investigated terrestrial outcrop sensing and integration with laser
scanning 3D models in ranges of up to a few hundred metres, whereas less
attention has been paid to ground-based imaging of more distant targets
such as mountain ridges, cliffs or the walls of large pits. Here we
investigate the potential of using such data in well-exposed Arctic
regions with steep topography as part of regional geological mapping
field campaigns, and to test how airborne hyperspectral data can be
combined with similar data collected on the ground or from moving
platforms such as a small ship. The region between the fjords Ikertoq
and Kangerlussuaq (Søndre Strømfjord) in West Greenland was selected for
a field study in the summer of 2016. This region is located in the
southern part of the Palaeoproterozoic Nagssugtoqidian orogen and
consists of high-grade metamorphic ortho- and paragneisses and metabasic
rocks (see below). A regional airborne hyperspectral data set (i.e.
HyMAP) was acquired here in 2002 (Tukiainen & Thorning 2005),
comprising 54 flight lines covering an area of c. 7500 km2;
19 of these flight lines were selected for the present study (Fig. 1).
The target areas visited in the field were selected on the basis of
preliminary interpretations of HyMap scenes and geology (Korstgård
1979). Two different sensors were utilised to acquire the new
hyperspectral data, predominantly a Specim AisaFenix
hyperspectral scanner due to its wide spectral range covering the
visible to near infrared and shortwave infrared parts of the
electromagnetic spectrum. A Rikola Hyperspectral Imager constituted a
secondary imaging system. It is much smaller and lighter than the Fenix
scanner, but is spectrally limited to the visible near infrared range.
The results obtained from combining the airborne hyperspectral data and
the Rikola instrument are presented in Salehi (2018), this volume. In
addition, representative samples of the main rock types were collected
for subsequent laboratory analysis. A parallel study was integrated with
geological and 3D photogrammetric mapping in Karrat region farther
north in West Greenland (Rosa et al. 2017; Fig. 1).
Original language | English |
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Pages (from-to) | 47-50 |
Number of pages | 4 |
Journal | Geological Survey of Denmark and Greenland Bulletin |
Volume | 41 |
DOIs | |
Publication status | Published - 15 Aug 2018 |
Programme Area
- Programme Area 4: Mineral Resources