David Marshall

Remote forcing of the Antarctic Circumpolar Current by diapycnal mixing

Geophysical Research Letters 38:8 (2011)

Authors:

DR Munday, LC Allison, HL Johnson, DP Marshall

Abstract:

We show that diapycnal mixing can drive a significant Antarctic Circumpolar Current (ACC) volume transport, even when the mixing is located remotely in northern-hemisphere ocean basins. In the case of remote forcing, the globally-averaged diapycnal mixing coefficient is the important parameter. This result is anticipated from theoretical arguments and demonstrated in a global ocean circulation model. The impact of enhanced diapycnal mixing on the ACC during glacial periods is discussed. Copyright 2011 by the American Geophysical Union.

Rossby wormholes

JOURNAL OF MARINE RESEARCH 69:2-3 (2011) 309-330

Spin-up and adjustment of the Antarctic Circumpolar Current and global pycnocline

JOURNAL OF MARINE RESEARCH 69:2-3 (2011) 167-189

Authors:

Lesley C Allison, Helen L Johnson, David P Marshall

Significant sink of ocean-eddy energy near western boundaries

Nature Geoscience 3:9 (2010) 608-612

Authors:

X Zhai, HL Johnson, DP Marshall

Abstract:

Ocean eddies generated through instability of the mean flow are a vital component of the energy budget of the global ocean1-3. In equilibrium, the sources and sinks of eddy energy have to be balanced. However, where and how eddy energy is removed remains uncertain3,4. Ocean eddies are observed to propagate westwards at speeds similar to the phase speeds of classical Rossby waves5, but what happens to the eddies when they encounter the western boundary is unclear. Here we use a simple reduced-gravity model along with satellite altimetry data to show that the western boundary acts as a "graveyardg" for the westward-propagating ocean eddies. We estimate a convergence of eddy energy near the western boundary of approximately 0.1-0.3 TW, poleward of 10°in latitude. This energy is most probably scattered into high-wavenumber vertical modes, resulting in energy dissipation and diapycnal mixing. If confirmed, this eddy-energy sink will have important implications for the ocean circulation. © 2010 Macmillan Publishers Limited. All rights reserved.

Idealised flow past an island in a dynamically adaptive finite element model

Ocean Dynamics 60:4 (2010) 835-850

Authors:

DR Munday, DP Marshall, MD Piggott

Abstract:

The problem of flow separation around islands is investigated using a dynamically adaptive finite element model to allow for resolution of the shear layers that form in the advent of separation. The changes in secondary circulation and vertical motion that occur in both attached and separated flows are documented, as is the degree of closure of the wake eddies. In the numerical experiments presented, the strongest motion always takes place at the sides of the idealised island, where flow curvature and shear act together to induce ascent. In contrast, it is the slower motion within the wake eddies that allow streamlines to extend from the bottom to the surface. We find no evidence for closure of the wake eddies. Rather, all of our separated experiments show that streamlines that pass through the eddies originate outside of the shear layers and frictional boundary layers on the upstream side of the idealised island. The numerical experiments demonstrate the potential for dynamically adaptive, unstructured meshes to resolve the separated shear layers that occur downstream of the idealised island, as well as the narrow boundary layers that form on the island itself. © 2010 Springer-Verlag.