Abstract
Turbidity currents dominate sediment transfer into the deep ocean, and can damage critical seabed infrastructure. It is commonly inferred that powerful turbidity currents are triggered by major external events, such as storms, river floods, or earthquakes. However, basic models for turbidity current triggering remain poorly tested, with few studies accurately recording precise flow timing. Here, we analyse the most detailed series of measurements yet made of powerful (up to 7.2 ms−1) turbidity currents, within Monterey Canyon, offshore California. During 18-months of instrument deployment, fourteen turbidity currents were directly monitored. No consistent triggering mechanism was observed, though flows did cluster around enhanced seasonal sediment supply. We compare turbidity current timing at Monterey Canyon (a sandy canyon-head fed by longshore drift) to the only other systems where numerous (>10-100) flows have been measured precisely via direct monitoring; the Squamish Delta (a sandy fjord-head delta), and the Congo Canyon (connected to the mud-dominated mouth of the Congo River). A common seasonal pattern emerges, leading to a new model for preconditioning and triggering of turbidity currents initiating through slope failure in areas of sediment accumulation, such as canyon heads or river mouths. In this model, rapid or sustained sediment supply alone can produce elevated pore pressures, which may persist, thereby predisposing slopes to fail. Once preconditioned, a range of minor external perturbations, such as moderate storm-waves, result in local pore pressure variation, and thus become effective triggers. Major external triggers are therefore not always a prerequisite for triggering of powerful turbidity currents.
Highlights
Turbidity currents are one of the most important processes for moving sediment across our planet, dominating transport from continental shelves to the deep sea, and play a key role in the transport and burial of organic carbon (Galy et al, 2007) and pol-lutants (Mordecai et al, 2011)
The Pajaro and San Lorenzo Rivers are detached from the head of Monterey Canyon, providing minor direct sediment input
We compare our results from Monterey Canyon with previously published observations from two other well-monitored submarine systems for which we provide further details in Supplementary Table S1
Summary
Turbidity currents are one of the most important processes for moving sediment across our planet, dominating transport from continental shelves to the deep sea, and play a key role in the transport and burial of organic carbon (Galy et al, 2007) and pol-lutants (Mordecai et al, 2011). Heezen and Ewing, 1952; Heezen et al, 1964; Piper et al, 1999; Hsu et al, 2008; Carter et al, 2009, 2012; Gavey et al, 2017; Pope et al, 2017) 95% of Salinas River sediment discharge enters Monterey Bay 6.7 km to the south of the canyon head (Watson et al, 2003; Casagrande and Watson, 2003). 3.2 0.0 moorings at sites ∼150 km from the coast record sufficiently long runout flows (N = 10; Azpiroz-Zabala et al, 2017; Simmons et al, 2020). Data from these two comparative sites allow us to compare patterns of flow timing in diverse physiographic settings with different sediment delivery mechanisms and grain sizes
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