Biomediation of submarine sediment gravity flow dynamics

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Biomediation of submarine sediment gravity flow dynamics. / Craig, Melissa; Baas, Jaco H.; Amos, Kathryn J. et al.
Yn: Geology, Cyfrol 48, Rhif 1, 01.2020, t. 72-76.

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

HarvardHarvard

Craig, M, Baas, JH, Amos, KJ, Strachan, LJ, Manning, AJ, Paterson, DM, Hope, JA, Nodder, SD & Baker, ML 2020, 'Biomediation of submarine sediment gravity flow dynamics', Geology, cyfrol. 48, rhif 1, tt. 72-76. https://doi.org/10.1130/G46837.1

APA

Craig, M., Baas, J. H., Amos, K. J., Strachan, L. J., Manning, A. J., Paterson, D. M., Hope, J. A., Nodder, S. D., & Baker, M. L. (2020). Biomediation of submarine sediment gravity flow dynamics. Geology, 48(1), 72-76. https://doi.org/10.1130/G46837.1

CBE

Craig M, Baas JH, Amos KJ, Strachan LJ, Manning AJ, Paterson DM, Hope JA, Nodder SD, Baker ML. 2020. Biomediation of submarine sediment gravity flow dynamics. Geology. 48(1):72-76. https://doi.org/10.1130/G46837.1

MLA

VancouverVancouver

Craig M, Baas JH, Amos KJ, Strachan LJ, Manning AJ, Paterson DM et al. Biomediation of submarine sediment gravity flow dynamics. Geology. 2020 Ion;48(1):72-76. Epub 2019 Tach 19. doi: 10.1130/G46837.1

Author

Craig, Melissa ; Baas, Jaco H. ; Amos, Kathryn J. et al. / Biomediation of submarine sediment gravity flow dynamics. Yn: Geology. 2020 ; Cyfrol 48, Rhif 1. tt. 72-76.

RIS

TY - JOUR

T1 - Biomediation of submarine sediment gravity flow dynamics

AU - Craig, Melissa

AU - Baas, Jaco H.

AU - Amos, Kathryn J.

AU - Strachan, Lorna J.

AU - Manning, Andrew J.

AU - Paterson, David M.

AU - Hope, Julie A.

AU - Nodder, Scott D.

AU - Baker, Megan L.

PY - 2020/1

Y1 - 2020/1

N2 - Sediment gravity flows are the primary process by which sediment and organic carbon are transported from the continental margin to the deep ocean. Up to 40% of the total marine organic cabon pool is represented by cohesive extracellular polymeric substances (EPS) produced by micro-organisms. The effect of these polymers on sediment gravity flows has not been investigated, despite the economic and societal importance of these flows. We present the first EPS concentrations measured in deep-sea sediment, combined with novel laboratory data that offer insights into the modulation of the dynamics of clay-laden, physically cohesive sediment gravity flows by biological cohesion. We show that EPS can profoundly affect the character, evolution and run-out of sediment gravity flows, and are as prevalent in deep oceans as in shallow seas. Transitional and laminar plug flows are more susceptible to EPS-induced changes in flow properties than turbulent flows. At relatively low concentrations, EPS markedly decrease the head velocity and run-out distance of transitional flows. This biological cohesion is greater, per unit weight, than the physical cohesion of cohesive clay and may exert a stronger control on flow behavior. These results significantly improve our understanding of the effect of an unrealized biological component of sediment gravity flows. The implications are wide ranging and may influence predictive models of sediment gravity flows and advance our understanding how these flows transport and bury organic carbon globally.

AB - Sediment gravity flows are the primary process by which sediment and organic carbon are transported from the continental margin to the deep ocean. Up to 40% of the total marine organic cabon pool is represented by cohesive extracellular polymeric substances (EPS) produced by micro-organisms. The effect of these polymers on sediment gravity flows has not been investigated, despite the economic and societal importance of these flows. We present the first EPS concentrations measured in deep-sea sediment, combined with novel laboratory data that offer insights into the modulation of the dynamics of clay-laden, physically cohesive sediment gravity flows by biological cohesion. We show that EPS can profoundly affect the character, evolution and run-out of sediment gravity flows, and are as prevalent in deep oceans as in shallow seas. Transitional and laminar plug flows are more susceptible to EPS-induced changes in flow properties than turbulent flows. At relatively low concentrations, EPS markedly decrease the head velocity and run-out distance of transitional flows. This biological cohesion is greater, per unit weight, than the physical cohesion of cohesive clay and may exert a stronger control on flow behavior. These results significantly improve our understanding of the effect of an unrealized biological component of sediment gravity flows. The implications are wide ranging and may influence predictive models of sediment gravity flows and advance our understanding how these flows transport and bury organic carbon globally.

U2 - 10.1130/G46837.1

DO - 10.1130/G46837.1

M3 - Article

VL - 48

SP - 72

EP - 76

JO - Geology

JF - Geology

SN - 0091-7613

IS - 1

ER -