A general criterion for the release of background potential energy through double diffusion
Accepted version
Peer-reviewed
Repository URI
Repository DOI
Change log
Authors
Abstract
Double diffusion occurs when the fluid density depends on two components that diffuse at different rates (e.g. heat and salt in the ocean). Double diffusion can lead to an up-gradient buoyancy flux and drive motion at the expense of potential energy. Here, we follow the work of Lorenz ( Tellus , vol. 7 (no. 2), 1955, pp. 157–167) and Winters et al. ( J. Fluid Mech. , vol. 289, 1995, pp. 115–128) for a single-component fluid and define the background potential energy (BPE) as the energy associated with an adiabatically sorted density field and derive its budget for a double-diffusive fluid. We find that double diffusion can convert BPE into available potential energy (APE), unlike in a single-component fluid, where the transfer of APE to BPE is irreversible. We also derive an evolution equation for the sorted buoyancy in a double-diffusive fluid, extending the work of Winters & D’Asaro ( J. Fluid Mech. , vol. 317, 1996, pp. 179–193) and Nakamura ( J. Atmos. Sci. , vol. 53 (no. 11), 1996, pp. 1524–1537). The criterion we develop for a release of BPE can be used to analyse the energetics of mixing and double diffusion in the ocean and other multiple-component fluids, and we illustrate its application using two-dimensional simulations of salt fingering.
Description
Journal Title
Conference Name
Journal ISSN
1469-7645
Volume Title
Publisher
Publisher DOI
Rights and licensing
Sponsorship
NERC (NE/L002507/1)
