Spatial and Temporal Patterns of Small-Scale Mixing in Drake Passage
Abstract
Temperature and salinity profiles obtained with expendable CTD probes throughout Drake Passage between February 2002 and July 2005 are analyzed to estimate turbulent diapycnal eddy diffusivities to a depth of 1000 m. Diffusivity values are inferred from density/temperature inversions and internal wave vertical strain. Both methods reveal the same pattern of spatial variability across Drake Passage; diffusivity estimates from inversions exceed those from vertical strain by a factor of 3 over most of Drake Passage. The Polar Front (PF) separates two dynamically different regions. Strong thermohaline intrusions characterize profiles obtained north of the PF. South of the PF, stratification is determined largely by salinity, and temperature is typically unstably stratified between 100- and 600-m depth. In the upper 400 m, turbulent diapycnal diffusivities are O(10^(−3) m2 s^(−1)) north of the PF but decrease to O(10^(−4) m2 s^(−1)) or smaller south of the PF. Below 400 m diffusivities typically exceed 10^(−4) m^2 s^(−1). Diffusivities decay weakly with depth north of the PF, whereas diffusivities increase with depth and peak near the local temperature maximum south of the PF. The meridional pattern in near-surface mixing corresponds to local maxima and minima of both wind stress and wind stress variance. Near-surface diffusivities are also found to be larger during winter months north of the PF. Wind-driven near-inertial waves, strong mesoscale eddy activity, and double-diffusive convection are suggested as possible factors contributing to observed mixing patterns
Additional Information
© 2007 American Meteorological Society. Manuscript received 9 November 2005, in final form 26 June 2006. XBT and XCTD sampling in Drake Passage is performed with the assistance of NSFsupported Raytheon Polar Services personnel and other cruise participants. Their support is appreciated and essential to the continued success of the sampling program. We thank Alberto Naveira Garabato both for conversations that led us to pursue this study and for sharing data from Drake Passage. We have also benefited from discussions with Jody Klymak, Eric Kunze, and Kurt Polzin and from two anonymous reviews. We gratefully acknowledge the following awards that have supported this research: an NDSEG Fellowship (A. F. Thompson), NSF OCE-0049066 (S. T. Gille), and NSF OPP-0337998 (J. Sprintall).Attached Files
Published - Thompson_etal_JPO2007.pdf
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Additional details
- Eprint ID
- 37772
- Resolver ID
- CaltechAUTHORS:20130404-153857440
- National Defense Science and Engineering Graduate (NDSEG) Fellowship
- NSF
- OCE-0049066
- NSF
- OPP-0337998
- Created
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2013-04-05Created from EPrint's datestamp field
- Updated
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2021-11-09Created from EPrint's last_modified field
- Caltech groups
- Division of Geological and Planetary Sciences