Your search keyword '"Wienkers, Aaron F."' showing total 3 results

1. Non-linear hydrodynamic instability and turbulence in eccentric astrophysical discs with vertical structure

Author

Wienkers, Aaron F. and Ogilvie, Gordon I.

Subjects

Astrophysics - Earth and Planetary Astrophysics, Astrophysics - High Energy Astrophysical Phenomena, Astrophysics - Solar and Stellar Astrophysics, Physics - Fluid Dynamics

Abstract

Non-linear evolution of the parametric instability of inertial waves inherent to eccentric discs is studied by way of a new local numerical model. Mode coupling of tidal deformation with the disc eccentricity is known to produce exponentially growing eccentricities at certain mean-motion resonances. However, the details of an efficient saturation mechanism balancing this growth still are not fully understood. This paper develops a local numerical model for an eccentric quasi-axisymmetric shearing box which generalises the often-used cartesian shearing box model. The numerical method is an overall second order well-balanced finite volume method which maintains the stratified and oscillatory steady-state solution by construction. This implementation is employed to study the non-linear outcome of the parametric instability in eccentric discs with vertical structure. Stratification is found to constrain the perturbation energy near the mid-plane and localise the effective region of inertial wave breaking that sources turbulence. A saturated marginally sonic turbulent state results from the non-linear breaking of inertial waves and is subsequently unstable to large-scale axisymmetric zonal flow structures. This resulting limit-cycle behaviour reduces access to the eccentric energy source and prevents substantial transport of angular momentum radially through the disc. Still, the saturation of this parametric instability of inertial waves is shown to damp eccentricity on a time-scale of a thousand orbital periods. It may thus be a promising mechanism for intermittently regaining balance with the exponential growth of eccentricity from the eccentric Lindblad resonances and may also help explain the occurrence of "bursty" dynamics such as the superhump phenomenon., Comment: 20 pages, 17 figures, accepted for publication in MNRAS

Published

2018

2. Rapid vertical exchange at fronts in the Northern Gulf of Mexico

Author

Qu, Lixin, Thomas, Leif N., Wienkers, Aaron F., Hetland, Robert D., Kobashi, Daijiro, Taylor, John R., Hsu, Fucent Hsuan Wei, MacKinnon, Jennifer A., Shearman, R. Kipp, and Nash, Jonathan D.

Published

2022

3. Rapid vertical exchange at fronts in the Northern Gulf of Mexico

Author

Lixin Qu, Leif N. Thomas, Aaron F. Wienkers, Robert D. Hetland, Daijiro Kobashi, John R. Taylor, Fucent Hsuan Wei Hsu, Jennifer A. MacKinnon, R. Kipp Shearman, Jonathan D. Nash, Qu, Lixin [0000-0002-2956-8949], Thomas, Leif N [0000-0002-0548-5786], Wienkers, Aaron F [0000-0002-8464-3139], Hetland, Robert D [0000-0001-9531-2119], Hsu, Fucent Hsuan Wei [0000-0003-0986-1678], MacKinnon, Jennifer A [0000-0002-7690-1185], and Apollo - University of Cambridge Repository

Subjects

Gulf of Mexico, Multidisciplinary, Rivers, 704/172/4081, article, General Physics and Astronomy, Water, General Chemistry, Seasons, 704/829/2737, Louisiana, 704/829/827, General Biochemistry, Genetics and Molecular Biology

Abstract

Over the Texas-Louisiana Shelf in the Northern Gulf of Mexico, the eutrophic, fresh Mississippi/Atchafalaya river plume isolates saltier waters below, supporting the formation of bottom hypoxia in summer. The plume also generates strong density fronts, features of the circulation that are known pathways for the exchange of water between the ocean surface and the deep. Using high-resolution ocean observations and numerical simulations, we demonstrate how the summer land-sea breeze generates rapid vertical exchange at the plume fronts. We show that the interaction between the land-sea breeze and the fronts leads to convergence/divergence in the surface mixed layer, which further facilitates a slantwise circulation that subducts surface water along isopycnals into the interior and upwells bottom waters to the surface. This process causes significant vertical displacements of water parcels and creates a ventilation pathway for the bottom water in the northern Gulf. The ventilation of bottom water can bypass the stratification barrier associated with the Mississippi/Atchafalaya river plume and might impact the dynamics of the region’s dead zone.

Published

2022