Rates of photochemical reactions within the snowpack, both on snow grains and in the firn air, depend on how actinic flux is attenuated as a function of depth. This snowpack photon flux can either be measured directly (e.g., with spectral radiometers in the snow) or indirectly (e.g., by chemical actinometry where the rate of a photochemical reaction is measured). In this work we use both techniques to measure the rate constant for nitrate photolysis on water-ice, j (NO3-), on the snowpack surface and beneath at Summit, Greenland during spring and summer. The surface measurements from these two methods are generally similar ((1-2)×10-7 s-1 during midday near the summer solstice) and follow expected diurnal and annual trends. In addition, both methods show a similar effect of snow albedo on photolysis at the surface: rate constants measured on the surface snow were approximately 45% higher than values predicted for the surface based on regressions of in-snow rate constants. Average (±σ) j (NO3-) e-folding depths (the depth along which the rate constant decreases by a factor of e) during the 2 field seasons are 10.3(±2.8) cm from actinometry tubes and 8.4(±2.4) cm from in-snow spectral radiometers. © 2006 Elsevier Ltd. All rights reserved.
CITATION STYLE
Galbavy, E. S., Anastasio, C., Lefer, B., & Hall, S. (2007). Light penetration in the snowpack at Summit, Greenland: Part 2 Nitrate photolysis. Atmospheric Environment, 41(24), 5091–5100. https://doi.org/10.1016/j.atmosenv.2006.01.066
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