Litcius/Paper detail

Deriving Snow Depth From ICESat-2 Lidar Multiple Scattering Measurements

Yongxiang Hu, Xiaomei Lu, Xubin Zeng, Snorre Stamnes, Thomas A. Neuman, N. T. Kurtz, Peng‐Wang Zhai, Meng Gao, Wenbo Sun, Kuan‐Man Xu, Zhaoyan Liu, Ali Omar, Rosemary R. Baize, Laura Rogers, Brandon O. Mitchell, Knut Stamnes, Yu‐Ping Huang, Nan Chen, Carl Weimer, Jennifer Lee, Zachary Fair

2022Frontiers in Remote Sensing31 citationsDOIOpen Access PDF

Abstract

Snow is a crucial element in the Earth’s system, but snow depth and mass are very challenging to be measured globally. Here, we provide the theoretical foundation for deriving snow depth directly from space-borne lidar (ICESat-2) snow multiple scattering measurements for the first time. First, based on the Monte Carlo lidar radiative transfer simulations of ICESat-2 measurements of 532-nm laser light propagation in snow, we find that the lidar backscattering path length follows Gamma distribution. Next, we derive three simple analytical equations to compute snow depth from the average, second-, and third-order moments of the distribution. As a preliminary application, these relations are then used to retrieve snow depth over the Antarctic ice sheet and the Arctic sea ice using the ICESat-2 lidar multiple scattering measurements. The robustness of this snow depth technique is demonstrated by the agreement of snow depth computed from the three derived relations using both modeled data and ICESat-2 observations.

Topics & Concepts

LidarSnowRemote sensingScatteringMonte Carlo methodRadiative transferAtmospheric radiative transfer codesGeologyEnvironmental scienceMeteorologyGeographyPhysicsOpticsMathematicsStatisticsCryospheric studies and observationsAtmospheric aerosols and cloudsMeteorological Phenomena and Simulations