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Image: Using the laser scanner on a nearby glacier, with our sled-mounted radar in the background.

Earth Sciences recently purchased a Terrestrial Laser Scanner (TLS). This is a tripod-mounted Leica P50 weighing around 30 kg all-in, which I took with me to West Antarctica for the winter season there. I was working as part of a British Antarctic Survey led project named DEFIANT, which aims to understand what has driven consistently poor and still declining sea ice conditions around the continent since 2016. ÐÂÏã¸ÛÁùºÏ²Ê¿ª½±½á¹û(via Prof Julienne Stroeve and Dr Rosemary Willatt) is providing the project with expertise in remote sensing technologies such as radars and lasers.

My colleague Vishnu Nandan and I used the instrument to map the centimetre-scale roughness of snow on sea ice, before scanning the same snow with radar instruments that simulate the functionality of satellite-mounted altimeters. The laser scanner produced digital elevation models of 1m2 snow patches with a spatial resolution of around one point per millimetre in about five minutes. Roughness on the centimetre scale is emerging as a key factor in determining whether radar waves will penetrate the snow surface, and this is the first time we’ve completed a dual radar/laser characterisation on sea ice with this resolution.

Figure: Two patches of snow (80 cm diameter) with different roughness characteristics. Snow on the left is flat on a large scale, and rough on a small scale. Snow on the right is rough on a large scall, and smooth on a small scale.

We focused our science on relatively small patches of snow; this was in part because that’s the patch size scanned by our radar in one shot, but also because the near-infrared wavelength of laser light used by the scanner does not reflect well from snow and ice surfaces (they’re very dark), so scanning icey surfaces more than 100 m away takes prohibitively long. The scanner must also be totally level for the duration of the scan, which was difficult for us as land-adjacent sea ice rises, bends and tilts with the tide, the waves and as you walk around on it. We found that the scanner worked excellently in temperatures down to -20°C, and the performance of its batteries in particular was outstanding.

“Before I flew home we picked out our favourite scientific instruments from the twenty-something that we took with us; the laser scanner came an impressive second, next only to the indomitable folding ruler.

We will now analyse the snow-patch DEMs produced by the scanner, with a focus on which statistical metrics contain the most information about the coincident radar data that we collected. Despite the historically poor sea ice conditions, our overwintering campaign was mostly a success. This was in large part due to the TLS.

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