Litcius/Paper detail

Biological Cohesion as the Architect of Bed Movement Under Wave Action

Xindi Chen, Changkuan Zhang, Ian Townend, David M. Paterson, Zheng Gong, Qin Jiang, Qian Feng, Xiping Yu

2021Geophysical Research Letters22 citationsDOIOpen Access PDF

Abstract

Abstract Cohesive extracellular polymeric substances (EPS) generated by microorganisms abundant on Earth are regarded as bed “stabilizers” increasing the erosion threshold in sedimentary systems. However, most observations of this phenomenon have been taken under steady flow conditions. In contrast, we present how EPS affect the bed movement under wave action, showing a destabilization of the system. We demonstrate a complex behavior of the biosedimentary deposits, which encompasses liquefaction, mass motion, varying bed formations and erosion, depending on the amount of EPS present. Small quantities of EPS induce higher mobility of the sediments, liquefying an otherwise stable bed. Bed with larger quantities of EPS undergoes a synchronized mechanical oscillation. Our analysis clarifies how biological cohesion can potentially put coastal wetlands at risk by increasing their vulnerability to waves. These findings lead to a revised understanding of the different roles played by microbial life, and their importance as mediators of seabed mobility.

Topics & Concepts

Cohesion (chemistry)SeabedLiquefactionSedimentary rockGeologyErosionCoastal erosionExtracellular polymeric substanceOscillation (cell signaling)Bed loadGeotechnical engineeringEnvironmental scienceSediment transportGeomorphologySedimentOceanographyChemistryGeochemistryPaleontologyBiochemistryBiofilmOrganic chemistryBacteriaCoastal wetland ecosystem dynamicsCoastal and Marine DynamicsMethane Hydrates and Related Phenomena