Energy- and momentum-conserving model of splash entrainment in sand and snow saltation

Despite being the main sediment entrainment mechanism in aeolian transport, granular splash is still poorly understood. We provide a deeper insight into the dynamics of sand and snow ejection with a stochastic model derived from the energy and momentum conservation laws. Our analysis highlights that the ejection regime of uniform sand is inherently different from that of heterogeneous sand. Moreover, we show that cohesive snow presents a mixed ejection regime, statistically controlled either by energy or momentum conservation depending on the impact velocity. The proposed formulation can provide a solid base for granular splash simulations in saltation models, leading to more reliable assessments of aeolian transport on Earth and Mars.

Energy- and momentum-conserving model of splash entrainment in sand and snow saltation

Experimental Study on Bedload Transport and Bedforms: Behaviour and Interplay in Steep Turbulent Streams

p Spatio-temporal deposition profile of an experimentally produced turbidity current with a continuous suspension supply

Measurement of the inner structure of turbidity currents by ultrasound velocity profiling

Experimental Study on Bedload Transport and Bedforms: Behaviour and Interplay in Steep Turbulent Streams

Measurement of the inner structure of turbidity currents by ultrasound velocity profiling

p Spatio-temporal deposition profile of an experimentally produced turbidity current with a continuous suspension supply