Abstract
Submarine channels parallel river channels in their ability to transport sediment. However, in contrast to rivers, sediment transport and bed-form development in submarine channels are less well understood. Many steep (>1°), sandy submarine channels are dominated by upstream-migrating bed forms. The flow conditions required to form these upstream-migrating bed forms remain debated because the interactions between turbidity currents and active bed forms are difficult to measure directly. Consequently, we used a depth-resolved numerical model to test the role of flow parameters that are hypothesized to control the formation of upstream-migrating bed forms in submarine channels. While our modeling results confirmed the importance of previously identified flow parameters (e.g., densiometric Froude number), we found that basal sediment concentration in turbidity currents is the strongest predictor of upstream-migrating bed-form formation. Our model shows how locally steep gradients enable high sediment concentrations (average?>5 vol%) in the basal parts of flows, which allow the development of cyclic step instabilities and their associated bed forms. This new insight explains the previously puzzling observation that upstream-migrating bed forms are abundant in proximal, steep, sandy reaches of submarine channels, while their occurrence becomes more intermittent downslope.
| Original language | English |
|---|---|
| Pages (from-to) | 1137-1142 |
| Number of pages | 6 |
| Journal | Geology |
| Volume | 51 |
| Issue number | 12 |
| DOIs | |
| Publication status | Published - 27 Sept 2023 |
Bibliographical note
Publisher Copyright:© (2023), (Geological Society of America). All Rights Reserved.
Funding
We thank D. Piper, J. Covault, an anonymous reviewer, and editor K. Benison for constructive reviews that greatly improved the manuscript. This research was supported by ExxonMobil, the National Oceanography Centre, the Natural Sciences and Engineering Research Council of Canada (RGPIN/341715–2013), Netherlands Organization for Scientific Research (NOW; 864.13.006), the Royal Society (DHF/ R1/180166), and the Natural Environment Research Council (UK) (NE/L009358/1, NE/P005780/1, NE/ P009190/1, NE/S009965/1, NE/S010068/1, NE/ We thank D. Piper, J. Covault, an anonymous reviewer, and editor K. Benison for constructive reviews that greatly improved the manuscript. This research was supported by ExxonMobil, the National Oceanography Centre, the Natural Sciences and Engineering Research Council of Canada (RGPIN/341715–2013), Netherlands Organization for Scientific Research (NOW; 864.13.006), the Royal Society (DHF/R1/180166), and the Natural Environment Research Council (UK) (NE/L009358/1, NE/P005780/1, NE/P009190/1, NE/S009965/1, NE/S010068/1, NE/R015953/1). Bathymetry data sets were collected by John Hughes Clarke (Bute Inlet, Squamish Prodelta) and the Seafloor Mapping Laboratory of California State University–Monterey Bay (Monterey Canyon, https://seafloor.otterlabs.org/).
| Funders | Funder number |
|---|---|
| Seafloor Mapping Laboratory of California State University | |
| Natural Sciences and Engineering Research Council of Canada | RGPIN/341715–2013 |
| UK Natural Environment Research Council | NE/S010068/1, NE/L009358/1, NE/S009965/1, NE/ P009190/1, NE/P005780/1 |
| Royal Statistics Society | DHF/ R1/180166 |
| Nederlandse Organisatie voor Wetenschappelijk Onderzoek | 864.13.006 |
| ExxonMobil Foundation | |
| National Oceanography Centre |