Cross-Comparison of Albedo Products for Glacier Surfaces Derived from Airborne and Satellite (Sentinel-2 and Landsat 8) Optical Data

Naegeli, Kathrin; Damm, Alexander; Huss, Matthias; Wulf, Hendrik; Schaepman, Michael E.; Hoelzle, Martin

doi:10.3390/rs9020110

Cited by 92 publications

(102 citation statements)

References 51 publications

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“…In agreement with previous satellite investigations on Alpine glaciers, low α VIS values are estimated in the Morteratsch ablation zone (Brun et al, 2015;Dumont et al, 2011;Fugazza et al, 2016;Klok et al, 2004;Naegeli et al, 2015Naegeli et al, , 2017. This decrease in albedo can be explained by both an increase in LAI content and/or variations of the snow and ice grain properties.…”

Section: Discussionsupporting

confidence: 90%

Impact of impurities and cryoconite on the optical properties of the Morteratsch Glacier (Swiss Alps)

et al. 2017

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Abstract. The amount of reflected energy by snow and ice plays a fundamental role in their melting processes. Different non-ice materials (carbonaceous particles, mineral dust (MD), microorganisms, algae, etc.) can decrease the reflectance of snow and ice promoting the melt. The object of this paper is to assess the capability of field and satellite (EO-1 Hyperion) hyperspectral data to characterize the impact of light-absorbing impurities (LAIs) on the surface reflectance of ice and snow of the Vadret da Morteratsch, a large valley glacier in the Swiss Alps. The spatial distribution of both narrow-band and broad-band indices derived from Hyperion was analyzed in relation to ice and snow impurities. In situ and laboratory reflectance spectra were acquired to characterize the optical properties of ice and cryoconite samples. The concentrations of elemental carbon (EC), organic carbon (OC) and levoglucosan were also determined to characterize the impurities found in cryoconite. Multi-wavelength absorbance spectra were measured to compare the optical properties of cryoconite samples and local moraine sediments. In situ reflectance spectra showed that the presence of impurities reduced ice reflectance in visible wavelengths by 80-90 %. Satellite data also showed the outcropping of dust during the melting season in the upper parts of the glacier, revealing that seasonal input of atmospheric dust can decrease the reflectance also in the accumulation zone of the glacier. The presence of EC and OC in cryoconite samples suggests a relevant role of carbonaceous and organic material in the darkening of the ablation zone. This darkening effect is added to that caused by fine debris from lateral moraines, which is assumed to represent a large fraction of cryoconite. Possible input of anthropogenic activity cannot be excluded and further research is needed to assess the role of human activities in the darkening process of glaciers observed in recent years.

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Section: Discussionsupporting

confidence: 90%

Impact of impurities and cryoconite on the optical properties of the Morteratsch Glacier (Swiss Alps)

et al. 2017

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“…In general, in the entire visible spectrum, the reflection is very high: about 90% for snow and 65% for ice of glaciers. In contrast, in the shortwave infrared spectral reflection can be even lower than 10% [32].…”

Section: Detection Accuracy Of the Marginal Zone Of Glaciers-landsat mentioning

confidence: 98%

“…For such selected pixels, local statistics were calculated in a moving window with a size of 2 × 2 pixels. Based on the knowledge of the spectral reflection characteristics of ice [32], it was assumed that a difference of less than 0.1 between the panNDSI index values will not allow for a detailed distinction of the ice-ground boundary ( Figure 3F). As the local variation increases for pixels arranged along the ice border, the higher the possibility of automatic or semiautomatic classification.…”

Section: Detection Accuracy Of the Marginal Zone Of Glaciers-landsat mentioning

confidence: 99%

Fluctuation of Glacial Retreat Rates in the Eastern Part of Warszawa Icefield, King George Island, Antarctica, 1979–2018

et al. 2018

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“…Several studies have estimated BRDFs and HCRFs of snow and sea ice surfaces (e.g. Hudson et al, 2006;Marks et al, 2015;Arnold et al, 2002), but equivalent measurements are scarce for glacier ice in various states of melt and impurity loading, although Naegeli et al (2015) measured HCRF for various surface types on an alpine glacier, and Gruell and de Ruyter de Wildt (1999) measured anisotropic reflection from melting glaciers in two Landsat Thematic Mapper bands. Naegeli et al (2017) recently showed that ice surfaces with higher impurity loads scatter more anisotropically, possibly due to locally enhanced melt.…”

Section: Characterising Abiotic Impuritiesmentioning

confidence: 99%

“…We have recently undertaken field work for this purpose and will publish the outcomes in a future paper. There is uncertainty in the biological literature concerning the impact of cell size on the optical properties of algae arising from the spatial distribution of pigments within cells (Haardt and Maske, 1987), variable intracellular architecture (Haardt and Maske, 1987), packaging effects (Morel and Bricaud, 1981) and non-linear relationships between cell growth and Figure 4. A constant biomass (0.5 mg algae /g ice , pigment mass fractions (% total cell dry mass) is 1.5 % chlorophyll a, 5 % primary and secondary carotenoids, 15 µm cell radius) distributed vertically in layers of ice (1500 µm grain radius) of varying thickness (1, 2, 3, 4, 5, 10 mm).…”

Section: Characterising the Optical Properties Of Individual Cellsmentioning

confidence: 99%

Quantifying bioalbedo: a new physically based model and discussion of empirical methods for characterising biological influence on ice and snow albedo

et al. 2017

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Abstract. The darkening effects of biological impurities on ice and snow have been recognised as a control on the surface energy balance of terrestrial snow, sea ice, glaciers and ice sheets. With a heightened interest in understanding the impacts of a changing climate on snow and ice processes, quantifying the impact of biological impurities on ice and snow albedo ("bioalbedo") and its evolution through time is a rapidly growing field of research. However, rigorous quantification of bioalbedo has remained elusive because of difficulties in isolating the biological contribution to ice albedo from that of inorganic impurities and the variable optical properties of the ice itself. For this reason, isolation of the biological signature in reflectance data obtained from aerial/orbital platforms has not been achieved, even when ground-based biological measurements have been available. This paper provides the cell-specific optical properties that are required to model the spectral signatures and broadband darkening of ice. Applying radiative transfer theory, these properties provide the physical basis needed to link biological and glaciological ground measurements with remotely sensed reflectance data. Using these new capabilities we confirm that biological impurities can influence ice albedo, then we identify 10 challenges to the measurement of bioalbedo in the field with the aim of improving future experimental designs to better quantify bioalbedo feedbacks. These challenges are (1) ambiguity in terminology, (2) characterising snow or ice optical properties, (3) characterising solar irradiance, (4) determining optical properties of cells, (5) measuring biomass, (6) characterising vertical distribution of cells, (7) characterising abiotic impurities, (8) surface anisotropy, (9) measuring indirect albedo feedbacks, and (10) measurement and instrument configurations. This paper aims to provide a broad audience of glaciologists and biologists with an overview of radiative transfer and albedo that could support future experimental design.

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Cross-Comparison of Albedo Products for Glacier Surfaces Derived from Airborne and Satellite (Sentinel-2 and Landsat 8) Optical Data

Cited by 92 publications

References 51 publications

Impact of impurities and cryoconite on the optical properties of the Morteratsch Glacier (Swiss Alps)

Impact of impurities and cryoconite on the optical properties of the Morteratsch Glacier (Swiss Alps)

Fluctuation of Glacial Retreat Rates in the Eastern Part of Warszawa Icefield, King George Island, Antarctica, 1979–2018

Quantifying bioalbedo: a new physically based model and discussion of empirical methods for characterising biological influence on ice and snow albedo

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