News Release

What causes pools below waterfalls to periodically fill with sediment?

New study published in Geology

Peer-Reviewed Publication

Geological Society of America

Plunge pool vs. Sediment filled

image: : Example of sediment filling and evacuation of sediment in a small waterfall plunge pool on Arroyo Seco, San Gabriel Mountains, California. Top: Plunge pool, free of sediment, in June 2006 with swimmer leaping. Bottom: The same plunge pool filled with sediment in March 2010 following a wildfire in 2009 that overwhelmed the pool with sediment. view more 

Credit: Top photo credit: Kelin X. Whipple, bottom photo credit: Michael P. Lamb.

Boulder, Colo., USA: Deep pools below waterfalls are popular recreational swimming spots, but sometimes they can be partially or completely filled with sediment. New research showed how and why pools at the base of waterfalls, known as plunge pools, go through natural cycles of sediment fill and evacuation. Beyond impacting your favorite swimming hole, plunge pools also serve important ecologic and geologic functions. Deep pools are refuges for fish and other aquatic animals in summer months when water temperatures in shallow rivers can reach lethal levels. Waterfalls also can liquefy sediment within the pool, potentially triggering debris flows that can damage property and threaten lives. Over geologic time, pools are importance because the energetic waterfall jet can erode the rock walls of the pool--slowly moving the waterfall upstream, while simultaneously creating a deep canyon in its wake.

Reporting in the journal Geology today, Joel Scheingross of the University of Nevada Reno, and Michael Lamb of the California Institute of Technology, provided a new theoretical framework to predict when plunge pools fill with sediment, and when they subsequently evacuate that sediment exposing the rock walls of the pool to erosion. They showed that waterfall plunge pools tend to fill with sediment during modest river floods when sediment is transported in the reach upstream of the waterfall, but the waterfall jet is too weak to move all the sediment it receives from upstream. In contrast, during large floods, a strong waterfall jet can more efficiently move sediment up and out of the pool, outpacing the delivery of sediment from upstream, and exposing bedrock to erosion.

Scheingross and Lamb showed that waterfall plunge pools are most likely to fill with sediment following landscape disturbances--such as wildfire or landslides--that cause large influxes of sediment to rivers, or during prolonged droughts when river floods are rare. This information is useful to scientists and land managers interested in maintaining habitat and mitigating natural hazards. They also showed that bedrock erosion in plunge pools likely occurs only during large, infrequent floods, which tend to happen every 10 years or even less frequently. Therefore, the slow march of waterfalls upstream over geologic time likely occurs by fits and starts at a cadence set by extreme flood events.

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Mass balance controls on sediment scour and bedrock erosion in waterfall plunge pools
Joel Scheingross and Michael Lamb
Contact: jscheingross@unr.edu, University of Nevada Reno, Department of Geological Sciences and Engineering, Reno, Nevada
URL: https://pubs.geoscienceworld.org/gsa/geology/article/doi/10.1130/G48881.1/598762/Mass-balance-controls-on-sediment-scour-and

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