Journal
NATURE COMMUNICATIONS
Volume 9, Issue -, Pages -Publisher
NATURE PUBLISHING GROUP
DOI: 10.1038/s41467-018-06260-8
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Funding
- National Key Basic Research Program of China [2014CB745000]
- National Key Research and Development Program of China [2016YFC1402605]
- National Natural Science Foundation of China [41706005, 91628302, 41521091]
- National program on Global Change and Air-Sea Interaction [GASI-02-PAC-ST-MSwin, GASI-02-PAC-ST-MSaut, GASI-IPOVAI-01-03, GASI-IPOVAI-01-02]
- NSFC-Shandong Joint Fund for Marine Science Research Centers [U1406401]
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Turbulent mixing, which is critically important for the equilibrium of ocean circulation, is controlled by finescale turbulent shear (S-2) of oceanic flows through shear instability. Although the relationship between S-2 and mixing is well understood, the latitude-dependent generation processes of S-2 remain poorly known due to the lack of geographically extensive, long-term finescale velocity measurements. Here, using one-year ADCP data from 17 moorings along 143 degrees E, we first show that the upper-ocean S-2 and its resultant mixing rate have a W-shaped latitudinal distribution in the tropical-extratropical northwest Pacific with peaks at 0-2 degrees N, 12-14 degrees N, and 20-22 degrees N, respectively. Further analyses reveal that these S-2 peaks are caused by vertically-sheared equatorial currents, parametric subharmonic instability of diurnal tide, and anticyclonic eddy's inertial chimney effect, respectively. As climate model simulations are sensitive to the mixing parameterizations, our findings highlight the need to incorporate the latitude-dependent generation mechanisms of S-2 to improve climate models' prediction capabilities.
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