A mechanistic model linking insect (Hydropsychidae) silk nets to incipient sediment motion in gravel-bedded streams

A mechanistic model linking insect (Hydropsychidae) silk nets to incipient sediment motion in gravel-bedded streams

Plants and animals affect stream morphodynamics across a range of scales, yet including biological traits of organisms in geomorphic process models remains a fundamental challenge. For example, laboratory experiments have shown that silk nets built by caddisfly larvae (Trichoptera: Hydropsychidae) c...

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Bibliographic Details
Published in:Journal of geophysical research. Earth surface Vol. 119; no. 9; pp. 1833 - 1852
Main Authors: Albertson, Lindsey K., Sklar, Leonard S., Pontau, Patricia, Dow, Michelle, Cardinale, Bradley J.
Format: Journal Article
Language:English
Published: Washington Blackwell Publishing Ltd 01-09-2014
Subjects:
Aquatic insects
Arctopsyche californica
Biological
Ceratopsyche
Creeks & streams
ecogeomorphology
ecosystem engineering
erosion
Grain size
Gravel
Hydropsychidae
Insects
Larvae
Mathematical models
niche differences
Particle size
Polyculture
Sediments
Shear stress
Silk
Species composition
Streams
Trichoptera
Vertical distribution
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Summary:Plants and animals affect stream morphodynamics across a range of scales, yet including biological traits of organisms in geomorphic process models remains a fundamental challenge. For example, laboratory experiments have shown that silk nets built by caddisfly larvae (Trichoptera: Hydropsychidae) can increase the shear stress required to initiate bed motion by more than a factor of 2. The contributions of specific biological traits are not well understood, however. Here we develop a theoretical model for the effects of insect nets on the threshold of sediment motion, τ*crit, that accounts for the mechanical properties, geometry, and vertical distribution of insect silk, as well as interactions between insect species. To parameterize the model, we measure the tensile strength, diameter, and number of silk threads in nets built by two common species of caddisfly, Arctopsyche californica and Ceratopsyche oslari. We compare model predictions with new measurements of τ*crit in experiments where we varied grain size and caddisfly species composition. The model is consistent with experimental results for single species, which show that the increase in τ*crit above the abiotic control peaks at 40–70% for 10–22 mm sediments and declines with increasing grain size. For the polyculture experiments, however, the model underpredicts the measured increase in τ*crit when two caddisfly species are present in sediments of larger grain sizes. Overall, the model helps explain why the presence of caddisfly silk can substantially increase the forces needed to initiate sediment motion in gravel‐bedded streams and also illustrates the challenge of parameterizing the behavior of multiple interacting species in a physical model. Key Points Caddisfly silk nets are incorporated into a model of incipient sediment motionSilk nets increase critical shear stress in gravel‐bedded streamsSpecies‐specific silk and behaviors control the range of grain sizes affected
Bibliography:ark:/67375/WNG-NRT57TBL-N
istex:F08D48B2844DE3F3A61B317771FC6FDFB5B49C47
the National Science Foundation - No. 1110571
ArticleID:JGRF20303
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:2169-9003
2169-9011
DOI:10.1002/2013JF003024