Spatiotemporal dynamics of snow erosion, deposition and horizontal mass flux

Philip Crivelli, Michael Lehning, Enrico Paterna
Cambridge University Press (CUP), 2019
Journal paper

The quantification of snow transport, both in wind tunnels and the field, apply particle counting methods limited to punctual sampling of relatively small volumes. Particle counting can only capture horizontal mass fluxes, failing to measure snow erosion or deposition. Herein, we present a novel low-cost sensor tool, based on a Microsoft Kinect, adapted to capture snow surface changes during snow drifting at unprecedented spatial and temporal resolutions. In the wind tunnel setting of these experiments we observe a balance between erosion and deposition at low wind speeds, while erosion is dominant at higher wind speeds. Significant differences in power spectral densities of surface mass flux and horizontal particle mass flux are observed. We show that for the saltation-length-scale parameter lambda = 1, the integrated particle flux can be used to estimate the total surface mass flux in the wind tunnel. This provides an important basis to interpret mass flux measurements in the field.

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Philip Crivelli, Michael Lehning, Enrico Paterna
Cambridge University Press (CUP), 2019
Journal paper

Abstract

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https://infoscience.epfl.ch/record/266558?ln=en

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Wind tunnel measurements of sediment mass fluxes in different dense live plant canopies

Michael Lehning, Benjamin Andreas Walter

Erosion, transport and deposition of soil or snow are processes that occur when the atmospheric turbulent boundary layer interacts with the ground. Vegetation on the ground is able to significantly modify these processes, usually resulting in reduced particle mass fluxes. Previous wind tunnel studies quantifying mass fluxes as a function of the wind speed mainly investigated bare sediment surfaces without vegeta-tion. However, studies investigating the sheltering effect of vegetation against wind erosion typically focused on the influence of the canopy density on the mass flux. We present a combination of both: Wind tunnel measurements of particle mass fluxes and vertical mass flux profiles in different dense live plant canopies as a function of the wind speed. The experiments were performed in the SLF boundary layer wind tunnel with an 8 m long test section and a cross section area of one square meter. Three canopies of different densities were investigated (0; 5 and 25 plants/m2). For the experiments, natural quartz sand was spread on the ground beneath the plants (ryegrass). A sediment sampler with 60 bins was used to measure the vertical mass flux profiles up to a height of 60 cm. The results are compared to previous measurements of the surface shear stress in similar canopies. First data analyses show an exponential decrease of the total mass flux Q as a function of the canopy density as found in many other studies. For the bare sand surface, Q shows the typical (uτ - uτ,th)3 increase with increasing wind speed or skin friction velocity uτ, where uτ,th is the threshold at the onset of particle erosion. Similar relations were found for the 5 and 25 plants/m2 setups, however, with significant differ-ences compared to the bare sand surface that can be explained by the strong spatial inhomogeneity of uτ for the canopy cases.

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Local snow transport and surface evolution processes in East Antarctica

Francesco Comola, Philip Crivelli, Wolf Hendrik Huwald, Michael Lehning, Eric Sauvageat, Varun Sharma, Nander Wever

In Antarctica, direct measurements of processes shaping the surface mass balance such as precipitation, accumulation and erosion, drifting and blowing snow, and sublimation, are sparse and challenging due to the extreme environment and related difficulties in measuring the variables of interest. An ongoing project, ‘Local Surface Mass Balance in East Antarctica’, is designed to address these processes at the local scale with the objective of relating near-surface atmospheric dynamics, drifting and blowing snow, snow properties, and resulting accumulation and erosion patterns. Two snow mass balance stations at Princess Elisabeth, Antarctica, (72S, 23E, 1380m.a.s.l.) are collecting data since December 2016, including standard meteorological instruments, snow particle counters and 3-D sonic anemometers for combined analysis of wind, turbulence and mass flux. Pre- and post-storm Terrestrial Laser Scans (TLS) record the resulting surface morphological changes. This contribution presents analysis and preliminary results of the turbulence and wind data to obtain vertically integrated mass flux estimates. Calculated surface roughness and friction velocities are used for establishing formulations of vertical profiles of drifting and blowing snow. Stability corrections, auto- and cross-correlation functions of wind and mass flux, as well as the lag-time between sonic anemometers and snow particle counters are investigated. It is shown which vertical profile shape leads to consistent mass flux estimates and how magnitudes of calculated mass fluxes compare to earlier estimates. The comparisons suggest that mass transport has rather been underestimated in early and several current studies.

2018

Wind tunnel

Wind tunnels are machines where an object is held stationary inside a tube, and air is blown around it to study the interaction between the object and the moving air. They are used to test the aer

Transport

Transport (in British English) or transportation (in American English) is the intentional movement of humans, animals, and goods from one location to another. Modes of transport include air, land (rai

Mass flux

In physics and engineering, mass flux is the rate of mass flow. Its SI units are kg m−2 s−1. The common symbols are j, J, q, Q, φ, or Φ (Greek lower or capital Phi), sometimes with subscript m to in