<p>The thickness of supraglacial debris affects the surface energy balance and retreat patterns of mountain glaciers. Therefore, knowing a debris layer’s thickness is crucial for understanding the magnitude and timeframe of glacier melt. Field- based ground-penetrating radar (GPR) has recently gained attention as a possible method for measuring debris thickness. Airborne assessments achieve extensive coverage and characterization, but the use of GPR for such platforms remains relatively unexplored. We investigated the performance of 960&thinsp;MHz and 2.6&thinsp;GHz GPR signals through dry laboratory rock debris, and of 960&thinsp;MHz over ∼&thinsp;2&thinsp;km of transects on the debris cover of Changri Nup Glacier, Nepal Himalaya. On the glacier, 960&thinsp;MHz profiles were characterized by no clear reflection from the ice interface and volumetric backscatter from within ∼&thinsp;10&ndash;40&thinsp;cm, a depth that corresponds to approximate ground-truth debris thicknesses on all transects. The laboratory results show that the lack of an ice-debris interface return in field data was likely caused by a weak dielectric contrast between solid ice and porous dry debris and that surface scatter is coherent but weak. This suggests that the debris-ice interface reflection was also likely coherent, supporting our conclusion of a weak dielectric contrast. The laboratory 2.6&thinsp;GHz results show significant penetration for only smaller clast sizes up to 4&thinsp;cm. We used a statistical approach to estimate ice depth from volumetric scatter, which gave reasonable agreement with ground-truth depth measurements. We conclude that a remote system operating near 1&thinsp;GHz could successfully estimate dry debris cover thicknesses based on depth of volumetric backscatter.</p>