Wind work at the air-sea interface: a modeling study in anticipation of future space missions

Abstract. Wind work at the air-sea interface is the transfer of kinetic energy between the ocean and the atmosphere and, as such, is an important part of the ocean-atmosphere coupled system. Wind work is defined as the scalar product of ocean wind stress and surface current, with each of these two variables spanning, in this study, a broad range of spatial and temporal scales, from 10 km to more than 3000 km and hours to months. These characteristics emphasize wind work's multiscale nature. In the absence of appropriate global observations, our study makes use of a new global, coupled ocean-atmosphere simulation, with horizontal grid spacing of 2–5 km for the ocean and 7 km for the atmosphere, analyzed for 12 months. We develop a methodology, both in physical and spectral spaces, to diagnose three different components of wind work that force distinct classes of ocean motions, including high-frequency internal gravity waves, such as near-inertial oscillations, low-frequency currents such as those associated with eddies, and seasonally averaged currents, such as zonal tropical and equatorial jets. The total wind work, integrated globally, has a magnitude close to 5 TW, a value that matches recent estimates. Each of the first two components that force high-frequency and low-frequency currents, accounts for ∼ 28 % of the total wind work and the third one that forces seasonally averaged currents, ∼ 44 %. These three components, when integrated globally, weakly vary with seasons but their spatial distribution over the oceans has strong seasonal and latitudinal variations. In addition, the high-frequency component that forces internal gravity waves, is highly sensitive to the collocation in space and time (at scales of a few hours) of wind stresses and ocean currents. Furthermore, the low-frequency wind work component acts to dampen currents with a size smaller than 250 km and strengthen currents with larger sizes. This emphasizes the need to perform a full kinetic budget involving the wind work and nonlinear advection terms as small and larger-scale low-frequency currents interact through these nonlinear terms. The complex interplay of surface wind stresses and currents revealed by the numerical simulation motivates the need for winds and currents satellite missions to directly observe wind work.

[1]  D. Menemenlis,et al.  Local Air‐Sea Interactions at Ocean Mesoscale and Submesoscale in a Western Boundary Current , 2022, Geophysical Research Letters.

[2]  A. Lawrence,et al.  Seasonality and spatial dependence of meso- and submesoscale ocean currents from along-track satellite altimetry , 2022, Journal of Physical Oceanography.

[3]  H. Aluie,et al.  Scale of oceanic eddy killing by wind from global satellite observations , 2021, Science Advances.

[4]  P. Shi,et al.  Ocean surface current multiscale observation mission (OSCOM): Simultaneous measurement of ocean surface current, vector wind, and temperature , 2021 .

[5]  P. Chang,et al.  Mesoscale Energy Balance and Air–Sea Interaction in the Kuroshio Extension: Low-Frequency versus High-Frequency Variability , 2021 .

[6]  D. Menemenlis,et al.  Three‐to‐Six‐Day Air–Sea Oscillation in Models and Observations , 2020, Geophysical Research Letters.

[7]  J. McWilliams,et al.  Recipes for How to Force Oceanic Model Dynamics , 2020, Journal of Advances in Modeling Earth Systems.

[8]  Shian-Jiann Lin,et al.  DYAMOND: the DYnamics of the Atmospheric general circulation Modeled On Non-hydrostatic Domains , 2019, Progress in Earth and Planetary Science.

[9]  D. Menemenlis,et al.  Global Estimates of the Energy Transfer From the Wind to the Ocean, With Emphasis on Near‐Inertial Oscillations , 2019, Journal of geophysical research. Oceans.

[10]  D. Chelton,et al.  The Winds and Currents Mission Concept , 2019, Front. Mar. Sci..

[11]  D. Menemenlis,et al.  Ocean‐Scale Interactions From Space , 2019, Earth and Space Science.

[12]  D. Menemenlis,et al.  Partitioning Ocean Motions Into Balanced Motions and Internal Gravity Waves: A Modeling Study in Anticipation of Future Space Missions , 2018, Journal of Geophysical Research: Oceans.

[13]  E. Joseph Metzger,et al.  The wind work input into the global ocean revealed by a 17-year global HYbrid coordinate ocean model reanalysis , 2018, Ocean Modelling.

[14]  J. McWilliams,et al.  Dampening of Submesoscale Currents by Air-Sea Stress Coupling in the Californian Upwelling System , 2018, Scientific Reports.

[15]  E. Joseph Metzger,et al.  A Primer on Global Internal Tide and Internal Gravity Wave Continuum Modeling in HYCOM and MITgcm , 2018, New Frontiers in Operational Oceanography.

[16]  H. Aluie Convolutions on the sphere: commutation with differential operators , 2018, GEM - International Journal on Geomathematics.

[17]  Dimitris Menemenlis,et al.  Ocean submesoscales as a key component of the global heat budget , 2018, Nature Communications.

[18]  J. McWilliams,et al.  Satellite Observations of Imprint of Oceanic Current on Wind Stress by Air-Sea Coupling , 2017, Scientific Reports.

[19]  Xiaoming Zhai Dependence of Energy Flux from the Wind to Surface Inertial Currents on the Scale of Atmospheric Motions , 2017 .

[20]  E. Chassignet,et al.  Impact of Horizontal Resolution (1/12° to 1/50°) on Gulf Stream Separation, Penetration, and Variability , 2017 .

[21]  A. Mariano,et al.  An improved near-surface velocity climatology for the global ocean from drifter observations , 2017 .

[22]  Zhitao Yu,et al.  The impact of ocean surface currents on global eddy kinetic energy via the wind stress formulation , 2017, Ocean Modelling.

[23]  B. Qiu,et al.  Submesoscale transition from geostrophic flows to internal waves in the northwestern Pacific upper ocean , 2017, Nature Communications.

[24]  D. Menemenlis,et al.  Seasonality of submesoscale dynamics in the Kuroshio Extension , 2016 .

[25]  M. Jeroen Molemaker,et al.  Modulation of Wind-Work by Oceanic Current Interaction with the Atmosphere , 2016 .

[26]  Dimitris Menemenlis,et al.  Mesoscale to submesoscale wavenumber spectra in Drake Passage , 2016 .

[27]  H. Simmons,et al.  Near-Inertial Internal Gravity Waves in the Ocean. , 2016, Annual review of marine science.

[28]  Jonathan Gula,et al.  Seasonality in submesoscale turbulence , 2015, Nature Communications.

[29]  Bo Qiu,et al.  Impact of oceanic-scale interactions on the seasonal modulation of ocean dynamics by the atmosphere , 2014, Nature Communications.

[30]  C. Wunsch,et al.  A Description of Local and Nonlocal Eddy-Mean Flow Interaction in a Global Eddy-Permitting State Estimate , 2014 .

[31]  Y. Sasai,et al.  Seasonal Mesoscale and Submesoscale Eddy Variability along the North Pacific Subtropical Countercurrent , 2014 .

[32]  Xiaoming Zhai On the wind mechanical forcing of the ocean general circulation , 2013 .

[33]  C. Eden,et al.  The influence of high‐resolution wind stress field on the power input to near‐inertial motions in the ocean , 2013 .

[34]  Andrea Molod,et al.  The impact of limiting ocean roughness on GEOS‐5 AGCM tropical cyclone forecasts , 2013 .

[35]  Alistair Adcroft,et al.  Routes to energy dissipation for geostrophic flows in the Southern Ocean , 2012, Nature Geoscience.

[36]  C. Wunsch,et al.  On the Wind Power Input to the Ocean General Circulation , 2012 .

[37]  D. Chelton,et al.  Global observations of nonlinear mesoscale eddies , 2011 .

[38]  Andrea Molod,et al.  Improvement of the GEOS‐5 AGCM upon updating the air‐sea roughness parameterization , 2011 .

[39]  M. Hecht,et al.  Emergence of Wind-Driven Near-Inertial Waves in the Deep Ocean Triggered by Small-Scale Eddy Vorticity Structures , 2011 .

[40]  J. Marshall,et al.  Scales, Growth Rates, and Spectral Fluxes of Baroclinic Instability in the Ocean , 2011 .

[41]  K. Polzin,et al.  TOWARD REGIONAL CHARACTERIZATIONS OF THE OCEANIC INTERNAL WAVEFIELD , 2010, 1007.2113.

[42]  C. Eden,et al.  Effects of mesoscale eddy/wind interactions on biological new production and eddy kinetic energy , 2009 .

[43]  T. Lee,et al.  ECCO2: High Resolution Global Ocean and Sea Ice Data Synthesis , 2008 .

[44]  Lee-Lueng Fu,et al.  Observing Oceanic Submesoscale Processes From Space , 2008 .

[45]  Nikolai Maximenko,et al.  Stationary mesoscale jet‐like features in the ocean , 2008 .

[46]  Wataru Ohfuchi,et al.  Deep ocean inertia‐gravity waves simulated in a high‐resolution global coupled atmosphere–ocean GCM , 2008 .

[47]  H. Sasaki,et al.  Observational evidence of alternating zonal jets in the world ocean , 2005 .

[48]  Patrice Klein,et al.  Wind ringing of the ocean in presence of mesoscale eddies , 2004 .

[49]  Toshiyuki Hibiya,et al.  Global estimates of the wind‐induced energy flux to inertial motions in the surface mixed layer , 2002 .

[50]  W. Young,et al.  Propagation of near-inertial oscillations through a geostrophic flow , 1997 .

[51]  S. Schubert,et al.  Climatology of the Simulated Great Plains Low-Level Jet and Its Contribution to the Continental Moisture Budget of the United States , 1995 .

[52]  W. Large,et al.  Oceanic vertical mixing: a review and a model with a nonlocal boundary layer parameterization , 1994 .

[53]  E. Kunze Near-Inertial Wave Propagation In Geostrophic Shear , 1985 .

[54]  W. Large,et al.  Open Ocean Momentum Flux Measurements in Moderate to Strong Winds , 1981 .

[55]  D. Lenschow,et al.  The characteristics of turbulent velocity components in the surface layer under convective conditions , 1977 .

[56]  J. Kondo,et al.  Air-sea bulk transfer coefficients in diabatic conditions , 1975 .

[57]  A. Yaglom,et al.  Heat and mass transfer between a rough wall and turbulent fluid flow at high Reynolds and Péclet numbers , 1974, Journal of Fluid Mechanics.

[58]  B. Qiu,et al.  Seasonality in Transition Scale from Balanced to Unbalanced Motions in the World Ocean , 2018 .

[59]  C. Frantzidis,et al.  Response to Reviewers Reviewer #1 , 2010 .

[60]  C. Wunsch,et al.  Ocean Circulation Kinetic Energy: Reservoirs, Sources, and Sinks , 2009 .

[61]  Stephen G. Yeager,et al.  Diurnal to decadal global forcing for ocean and sea-ice models: The data sets and flux climatologies , 2004 .

[62]  R. H. Clarke,et al.  Observational studies in the atmospheric boundary layer , 1970 .