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Monitoring spatial and temporal variations of surface albedo on Saint Sorlin Glacier (French Alps) using terrestrial photography

Cryosphere (2011) 5(3) 759-771
DOI: 10.5194/tc-5-759-2011
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Abstract

Accurate knowledge of temperate glacier mass balance is essential to understand the relationship between glacier and climate. Defined as the reflected fraction of incident radiation over the whole solar spectrum, the surface broadband albedo is one of the most important variable in a glacier's mass balance. This study presents a new method to retrieve the albedo of frozen surfaces from terrestrial photography at visible and near infrared wavelengths. This method accounts for the anisotropic reflectance of snow and ice surfaces and uses a radiative transfer model for narrow-to-broadband conversion. The accuracy of the method was assessed using concomitant measurements of albedo during the summers 2008 and 2009 on Saint Sorlin Glacier (Grandes Rousses, France). These albedo measurements are performed at two locations on the glacier, one in the ablation area and the other in the accumulation zone, with a net radiometer Kipp and Zonen CNR1. The main sources of uncertainty are associated with the presence of high clouds and the georeferencing of the photographs. © Author(s) 2011.

Figures

  • Fig. 1. (a) Geometric configuration of the lighting and observation directions. (b) Definition of the relative geometry between a glacier pixel, the sun, and the camera (adapted from Sirguey et al., 2009).
  • Table 1. Wavelengths of maximum spectral sensivity λc of the two cameras. The measurements of camera spectral sensitivity (Demircan et al., 2000) have been conducted using a monochromatic source and a spectro-gonioradiometer (Brissaud et al., 2004). In this study, the spectral sensitivity of each channel is approximated by a Dirac delta distribution δλc .
  • Fig. 2. Map of Saint Sorlin Glacier. Location of the AWS used for validation during summer 2008 and summer 2009 are indicated on the glacier. The cameras take photographs from the hut. Etendard peak is also indicated.
  • Fig. 3. Ratio α(SSA=150m 2 kg−1) α(SSA=30m2 kg−1) , for six wavelentghs and as a function of the incident zenith angle, θi. (a) Pure snow; (b) snow contaminated with soot (1 ppm).
  • Fig. 4. Visible photography of the Saint Sorlin Glacier (left) and the derived albedo map (right) on 13 June 2009 12:00 LT (a) and 4 August 2009 12:00 LT (b).
  • Fig. 5. Comparison between the albedo retrieved from terrestrial photography and the albedo measured by the AWS during the summer 2008. The gray area depicts the uncertainties of albedo measurements (±10 %). The squares and the circles correspond to the albedo estimated from the photographs while ignoring the anisotropic reflectance of snow and ice. The dots and crosses show the albedo estimated while modelling the anisotropy.
  • Table 2. Mean (m) and root mean square deviation (q) of the difference between the albedo retrieved from terrestrial photography and the albedo measured at the AWS. The subscript iso corresponds to the results when ice and snow were assumed to be Lambertian surfaces. The subscript ani corresponds to the results obtained while considering the anisotropy factor. The confidence intervals on q(CI) were computed at the 99 % confidence level as explained in Sirguey (2009, Appendix B).
  • Fig. 6. Comparison between the albedo retrieved from terrestrial photography and the albedo measured by the AWS during the summer 2009. The gray area depicts the uncertainties of albedo measurements (±10 %). The squares and the circles correspond to the albedo estimated from the photographs while ignoring the anisotropic reflectance of snow and ice. The dots and crosses show the albedo estimated while modelling the anisotropy.

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CITATION STYLE

APA

Dumont, M., Sirguey, P., Arnaud, Y., & Six, D. (2011). Monitoring spatial and temporal variations of surface albedo on Saint Sorlin Glacier (French Alps) using terrestrial photography. Cryosphere, 5(3), 759–771. https://doi.org/10.5194/tc-5-759-2011

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