Buoyancy-Driven Coastal Currents off Oregon during Fall and Winter Public Deposited

Downloadable Content

Download PDF


Attribute NameValues
  • During fall/winter off the Oregon coast, oceanographic surveys are relatively scarce because of rough weather conditions. This challenge has been overcome by the use of autonomous underwater gliders deployed along the Newport hydrographic line (NH-Line) nearly continuously since 2006. The discharge from the coastal rivers between northern California and the NH-Line reach several thousands of cubic meters per second, and the peaks are comparable to the discharge from the Columbia River. This freshwater input creates cross-shelf density gradients that together with the wind forcing and the large-scale Davidson Current results in strong northward velocities over the shelf. A persistent coastal current during fall/winter, which the authors call the Oregon Coastal Current (OCC), has been revealed by the glider dataset. Based on a two-layer model, the dominant forcing mechanism of the OCC is buoyancy, followed by the Davidson Current and then the wind stress, accounting for 61% (±22.6%), 26% (±18.6%), and 13% (±11.7%) of the alongshore transports, respectively. The OCC average velocities vary from 0.1 to over 0.5 m s⁻¹, and transports are on average 0.08 (±0.07) Sverdrups (Sv; 1 Sv = 10⁶ m³ s⁻¹), with the maximum observed value of 0.49 Sv, comparable to the summertime upwelling jet off the Oregon coast. The OCC is a surface-trapped coastal current, and its geometry is highly affected by the wind stress, consistent with Ekman dynamics. The wind stress has an overall small direct contribution to the alongshore transport; however, it plays a primary role in modifying the OCC structure. The OCC is a persistent, key component of the fall/winter shelf dynamics and influences the ocean biogeochemistry off the Oregon coast.
Resource Type
Date Available
Date Issued
  • Mazzini, P. L. F., Barth, J. A., Shearman, R. K., & Erofeev, A. (2014). Buoyancy-Driven Coastal Currents off Oregon during Fall and Winter. Journal of Physical Oceanography, 44(11), 2854-2876. doi:10.1175/JPO-D-14-0012.1
Journal Title
Journal Volume
  • 44
Journal Issue/Number
  • 11
Rights Statement
Funding Statement (additional comments about funding)
  • P. L. F. Mazzini was supported by the Brazil–U.S. CAPES/Fulbright scholarship. Support for the field work and J. A. Barth, R. K. Shearman, and A. Erofeev was provided by the U.S. National Science Foundation Grants OCE-0527168 and OCE-0961999.
Peer Reviewed



This work has no parents.