Litcius/Paper detail

Limits to timescale dependence in erosion rates: Quantifying glacial and fluvial erosion across timescales

Joel Wilner, Bailey Nordin, Alexander Getraer, Rowan M. Gregoire, Mansa Krishna, Jiawen Li, Derek Pickell, Emma R. Rogers, Kalin T. McDannell, M. C. Palucis, C. Brenhin Keller

2024Science Advances17 citationsDOIOpen Access PDF

Abstract

Earth's topography and climate result from the competition between uplift and erosion, but it has been debated whether rivers or glaciers are more effective erosional agents. We present a global compilation of fluvial and glacial erosion rates alongside simple numerical experiments, which show that the "Sadler effect," wherein geological rates show an inverse relationship with measurement timescale, comprises three distinct effects: a measurement thickness bias, a bias of erosion and redeposition, and a bias introduced by not observing quiescent intervals. Furthermore, we find that, globally, average glacial erosion rates exceed fluvial erosion rates through time by an order of magnitude, and that this difference cannot be explained by Sadlerian biases or by variations in hillslope, precipitation, or latitude. These findings support observations of increased erosion rates following Cenozoic cooling and glaciation, and reveal the importance of glacial erosion over millennial to orogenic timescales.

Topics & Concepts

FluvialGlacial periodErosionGlacierGeologyPhysical geographyClimate changeLast Glacial MaximumPrecipitationGeomorphologyOceanographyGeographyMeteorologyStructural basinGeology and Paleoclimatology ResearchLandslides and related hazardsGeological formations and processes