Professor John Ryan Taylor

My research focuses on the fluid dynamics of the ocean. I am particularly interested in ocean turbulence and mixing, ocean fronts and the surface boundary layer, and the impact of turbulence on micro-organisms. Recent work has uncovered a fascinating and poorly-understood collection of processes occurring at relatively small scales (<O(10km)) where the vertical motion is strong but stratification and the Earth's rotation are important factors. Since these motions are too small to be directly resolved by global ocean and climate models, understanding their impact on the structure and dynamics of the ocean is one of the most pressing topics in physical oceanography. Currently, I am studying the dynamics of upper ocean fronts, the turbulent boundary layer beneath melting ice shelves, stratified turbulence, and the influence of physical processes on biogeochemical dynamics. Please see my homepage (linked on the right) for more information.

Publications

The influence of submesoscales and vertical mixing on the export of sinking tracers in large-eddy simulations The influence of submesoscales and vertical mixing on the export of sinking tracers in large-eddy simulations

JR Taylor, KM Smith, CA Vreugdenhil

– Journal of Physical Oceanography

(2020)

50,

1319

(doi: 10.1175/jpo-d-19-0267.1)

Submesoscales Enhance Storm-Driven Vertical Mixing of Nutrients: Insights From a Biogeochemical Large Eddy Simulation

DB Whitt, M Lévy, JR Taylor

– Journal of Geophysical Research - Oceans

(2019)

124,

8140

(doi: 10.1029/2019jc015370)

Testing the assumptions underlying ocean mixing methodologies using direct numerical simulations

JR Taylor, SM de Bruyn Kops, CP Caulfield, PF Linden

– Journal of Physical Oceanography

(2019)

49,

2761

(doi: 10.1175/JPO-D-19-0033.1)

The evolution of a front in turbulent thermal wind balance. Part 2. Numerical simulations

MN Crowe, JR Taylor

– Journal of Fluid Mechanics

(2019)

880,

326

(doi: 10.1017/jfm.2019.688)

Baroclinic instability with a simple model for vertical mixing Baroclinic instability with a simple model for vertical mixing

MN Crowe, JR Taylor

– Journal of Physical Oceanography

(2019)

49,

3273

(doi: 10.1175/JPO-D-18-0270.1)

Stratification effects in the turbulent boundary layer beneath a melting ice shelf: insights from resolved large-eddy simulations Stratification effects in the turbulent boundary layer beneath a melting ice shelf: insights from resolved large-eddy simulations

CA Vreugdenhil, JR Taylor

– Journal of Physical Oceanography

(2019)

49,

1905

(doi: 10.1175/JPO-D-18-0252.1)

Parameterization of frontal symmetric instabilities. I: Theory for resolved fronts (vol 109, pg 72, 2017)

SD Bachman, B Fox-Kemper, JR Taylor, LN Thomas

– Ocean Modelling

(2019)

137,

(doi: 10.1016/j.ocemod.2019.03.005)

The evolution and arrest of a turbulent stratified oceanic bottom boundary layer over a slope: Downslope regime

X Ruan, AF Thompson, JR Taylor

– Journal of Physical Oceanography

(2018)

49,

469

(doi: 10.1175/JPO-D-18-0079.1)

The Growth and Saturation of Submesoscale Instabilities in the Presence of a Barotropic Jet

MA Stamper, JR Taylor, B Fox-Kemper

– Journal of Physical Oceanography

(2018)

48,

2779

(doi: 10.1175/JPO-D-18-0022.1)

The evolution of a front in turbulent thermal wind balance. Part 1. Theory

MN Crowe, JR Taylor

– Journal of Fluid Mechanics

(2018)

850,

179

(doi: 10.1017/jfm.2018.448)

Atmosphere-Ocean Dynamics Group

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