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References (101)
-
J. Storch, C. Eden, I. Fast, H. Haak, D. Hernández‐Deckers, E. Maier‐Reimer, J. Marotzke, D. Stammer (2012)
An estimate of Lorenz energy cycle for the world ocean based on the 1/10º STORM/NCEP simulationJournal of Physical Oceanography, 42
-
T. Bell (1978)
Radiation damping of inertial oscillations in the upper oceanJournal of Fluid Mechanics, 88
-
M. Gregg (1989)
Scaling turbulent dissipation in the thermoclineJournal of Geophysical Research, 94
-
P. Müller (1976)
On the diffusion of momentum and mass by internal gravity wavesJournal of Fluid Mechanics, 77
-
D. Olbers (2017)
Internal gravity waves -
D. Fritts, T. Vanzandt (1993)
Spectral estimates of gravity wave energy and momentum fluxes. Part I: Energy dissipation, acceleration, and constraintsJournal of the Atmospheric Sciences, 50
-
A. Rimac, J. Storch, C. Eden, H. Haak (2013)
The influence of high‐resolution wind stress field on the power input to near‐inertial motions in the oceanGeophysical Research Letters, 40
-
E. Becker (2012)
Dynamical Control of the Middle AtmosphereSpace Science Reviews, 168
-
C. Whalen, Lynne Talley, J. MacKinnon (2012)
Spatial and temporal variability of global ocean mixing inferred from Argo profilesGeophysical Research Letters, 39
-
E. Becker, C. McLandress (2009)
Consistent Scale Interaction of Gravity Waves in the Doppler Spread ParameterizationJournal of the Atmospheric Sciences, 66
-
T. Dunkerton, D. Fritts (1984)
Transient gravity wave-critical layer interaction. I Convective adjustment and the mean zonal accelerationJournal of the Atmospheric Sciences, 41
-
R. Garcia, D. Marsh, D. Kinnison, B. Boville, F. Sassi (2007)
Simulation of secular trends in the middle atmosphere, 1950–2003Journal of Geophysical Research, 112
-
J. Nycander (2005)
Generation of internal waves in the deep ocean by tidesJournal of Geophysical Research, 110
-
J. Cairns, G. Williams (1976)
Internal wave observations from a midwater float, 2Journal of Geophysical Research, 81
-
D. Andrews, M. McIntyre (1976)
Planetary Waves in Horizontal and Vertical Shear: The Generalized Eliassen-Palm Relation and the Mean Zonal AccelerationJournal of the Atmospheric Sciences, 33
-
A. Tandon, C. Garrett (1996)
On a Recent Parameterization of Mesoscale EddiesJournal of Physical Oceanography, 26
-
J. Goff, B. Arbic (2010)
Global prediction of abyssal hill roughness statistics for use in ocean models from digital maps of paleo-spreading rate, paleo-ridge orientation, and sediment thicknessOcean Modelling, 32
-
J. Scinocca (2003)
An Accurate Spectral Nonorographic Gravity Wave Drag Parameterization for General Circulation ModelsJournal of the Atmospheric Sciences, 60
-
K. Watson (1990)
The Coupling of Surface and Internal Gravity Waves: RevisitedJournal of Physical Oceanography, 20
-
K. Hasselmann (1967)
WEAK-INTERACTION THEORY OF OCEAN WAVES -
M. Lighthill (1952)
On sound generated aerodynamically I. General theoryProceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 211
-
D. Fritts, M. Alexander (2003)
Gravity wave dynamics and effects in the middle atmosphereReviews of Geophysics, 41
-
T. Bell (1975)
Topographically generated internal waves in the open oceanJournal of Geophysical Research, 80
-
W. Dewar, A. Hogg (2010)
Topographic inviscid dissipation of balanced flowOcean Modelling, 32
-
N. McFarlane (1987)
The Effect of Orographically Excited Gravity Wave Drag on the General Circulation of the Lower Stratosphere and TroposphereJournal of the Atmospheric Sciences, 44
-
D. Fritts, S. Vadas, K. Wan, J. Werne (2006)
Mean and variable forcing of the middle atmosphere by gravity wavesJournal of Atmospheric and Solar-Terrestrial Physics, 68
-
Malte Müller, J. Cherniawsky, M. Foreman, J. Storch (2012)
Global M2 internal tide and its seasonal variability from high resolution ocean circulation and tide modelingGeophysical Research Letters, 39
-
B. Dushaw, P. Worcester, M. Dzieciuch (2011)
On the predictability of mode-1 internal tides, 58
-
M. Miller, T. Palmer, R. Swinbank (1989)
Parametrization and influence of subgridscale orography in general circulation and numerical weather prediction modelsMeteorology and Atmospheric Physics, 40
-
E. Kunze, S. Smith (2004)
The Role of Small-Scale Topography in Turbulent Mixing of the Global OceanOceanography, 17
-
M. Alford (2001)
Internal Swell Generation: The Spatial Distribution of Energy Flux from the Wind to Mixed Layer Near-Inertial MotionsJournal of Physical Oceanography, 31
-
S. Jayne, L. Laurent (2001)
Parameterizing tidal dissipation over rough topographyGeophysical Research Letters, 28
-
C. McComas (1977)
Equilibrium Mechanisms within the Oceanic Internal Wave FieldJournal of Physical Oceanography, 7
-
C. Eden, D. Olbers (2017)
A Closure for Internal Wave–Mean Flow Interaction. Part II: Wave DragJournal of Physical Oceanography, 47
-
C. Wunsch, R. Ferrari (2004)
VERTICAL MIXING, ENERGY, AND THE GENERAL CIRCULATION OF THE OCEANSAnnual Review of Fluid Mechanics, 36
-
J. Richter, F. Sassi, R. Garcia (2010)
Toward a Physically Based Gravity Wave Source Parameterization in a General Circulation ModelJournal of the Atmospheric Sciences, 67
-
J. Polton, Jerome Smith, Jennifer MacKinnon, A. Tejada-Martínez (2008)
Rapid generation of high‐frequency internal waves beneath a wind and wave forced oceanic surface mixed layerGeophysical Research Letters, 35
-
M. Nikurashin, R. Ferrari (2011)
Global energy conversion rate from geostrophic flows into internal lee waves in the deep oceanGeophysical Research Letters, 38
-
Erdal Yiğit, A. Aylward, A. Medvedev (2008)
Parameterization of the effects of vertically propagating gravity waves for thermosphere general circulation models: Sensitivity studyJournal of Geophysical Research, 113
-
E. Kunze, E. Firing, J. Hummon, T. Chereskin, A. Thurnherr (2006)
Global Abyssal Mixing Inferred from Lowered ADCP Shear and CTD Strain ProfilesJournal of Physical Oceanography, 36
-
M. Charron, E. Manzini (2002)
Gravity Waves from Fronts: Parameterization and Middle Atmosphere Response in a General Circulation ModelJournal of the Atmospheric Sciences, 59
-
D. Fritts, T. Dunkerton (1984)
A Quasi-Linear Study of Gravity-Wave Saturation and Self-AccelerationJournal of the Atmospheric Sciences, 41
-
Nils Brueggemann, C. Eden (2015)
Routes to Dissipation under Different Dynamical ConditionsJournal of Physical Oceanography, 45
-
C. Hines (1997)
Doppler-spread parameterization of gravity-wave momentum deposition in the middle atmosphere. Part 1: Basic formulationJournal of Atmospheric and Solar-Terrestrial Physics, 59
-
K. Hasselmann, T. Barnett, E. Bouws, H. Carlson, D. Cartwright, K. Enke, J. Ewing, H. Gienapp, D. Hasselmann, P. Kruseman, A. Meerburg, P. Müller, D. Olbers, K. Richter, W. Sell, H. Walden (1973)
Measurements of wind-wave growth and swell decay during the Joint North Sea Wave Project (JONSWAP), 12
-
P. Müller, D. Olbers (1975)
On the dynamics of internal waves in the deep oceanJournal of Geophysical Research, 80
-
Shuguang Wang, Fuqing Zhang (2010)
Source of Gravity Waves within a Vortex-Dipole Jet Revealed by a Linear ModelJournal of the Atmospheric Sciences, 67
-
D. Olbers, K. Herterich (1979)
The spectral energy transfer from surface waves to internal wavesJournal of Fluid Mechanics, 92
-
K. Polzin, Y. Lvov (2010)
TOWARD REGIONAL CHARACTERIZATIONS OF THE OCEANIC INTERNAL WAVEFIELDReviews of Geophysics, 49
-
Y. Desaubies (1976)
Analytical Representation of Internal Wave SpectraJournal of Physical Oceanography, 6
-
P. Cummins, G. Holloway, E. Gargett (1990)
Sensitivity of the GFDL Ocean General Circulation Model to a Parameterization of Vertical DiffusionJournal of Physical Oceanography, 20
-
D. Olbers, C. Eden (2017)
A Closure for Internal Wave-Mean Flow Interaction. Part I: Energy ConversionJournal of Physical Oceanography, 47
-
C. Warner, M. McIntyre (2001)
An Ultrasimple Spectral Parameterization for Nonorographic Gravity WavesJournal of the Atmospheric Sciences, 58
-
P. Müller, D. Olbers, J. Willebrand (1978)
The Iwex spectrumJournal of Geophysical Research, 83
-
B. Arbic, J. Shriver, P. Hogan, H. Hurlburt, J. McClean, E. Metzger, R. Scott, Ayon Sen, O. Smedstad, A. Wallcraft (2009)
Estimates of bottom flows and bottom boundary layer dissipation of the oceanic general circulation from global high-resolution modelsJournal of Geophysical Research, 114
-
R. Lindzen (1981)
Turbulence and stress owing to gravity wave and tidal breakdownJournal of Geophysical Research, 86
-
C. Eden, L. Czeschel, D. Olbers (2014)
Toward Energetically Consistent Ocean ModelsJournal of Physical Oceanography, 44
-
M. Alexander, T. Dunkerton (1999)
A spectral parameterization of mean-flow forcing due to breaking gravity wavesJournal of the Atmospheric Sciences, 56
-
G. Nastrom, K. Gage (1985)
A Climatology of Atmospheric Wavenumber Spectra of Wind and Temperature Observed by Commercial AircraftJournal of the Atmospheric Sciences, 42
-
D. Olbers (1983)
Models of the oceanic internal wave fieldReviews of Geophysics, 21
-
C. Eden, R. Greatbatch (2008)
Diapycnal mixing by meso-scale eddiesOcean Modelling, 23
-
Friederike Pollmann, C. Eden, D. Olbers (2017)
Evaluating the Global Internal Wave Model IDEMIX Using Finestructure MethodsJournal of Physical Oceanography, 47
-
C. Garrett, W. Munk (1972)
Space-Time scales of internal wavesGeophysical and Astrophysical Fluid Dynamics, 3
-
P. Müller, G. Holloway, F. Henyey, N. Pomphrey (1986)
Nonlinear interactions among internal gravity wavesReviews of Geophysics, 24
-
C. Eden (2015)
Revisiting the Energetics of the Ocean in Boussinesq ApproximationJournal of Physical Oceanography, 45
-
F. Senf, U. Achatz (2011)
On the impact of middle-atmosphere thermal tides on the propagation and dissipation of gravity wavesJournal of Geophysical Research, 116
-
S. Thorpe (1975)
The excitation, dissipation, and interaction of internal waves in the deep oceanJournal of Geophysical Research, 80
-
D. Olbers, C. Eden (2016)
Revisiting the Generation of Internal Waves by Resonant Interaction with Surface WavesJournal of Physical Oceanography, 46
-
R. Scott, J. Goff, A. Garabato, A. Nurser (2011)
Global rate and spectral characteristics of internal gravity wave generation by geostrophic flow over topographyJournal of Geophysical Research, 116
-
T. Shaw (2009)
Energy and momentum consistency in subgrid-scale parameterization for climate models -
F. Bretherton, C. Garrett (1968)
Wavetrains in inhomogeneous moving mediaProceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 302
-
G. Whitham (1970)
Two-timing, variational principles and wavesJournal of Fluid Mechanics, 44
-
M. Berry, K. Mount (1972)
Semiclassical approximations in wave mechanicsReports on Progress in Physics, 35
-
C. McLandress, T. Shepherd (2009)
Simulated Anthropogenic Changes in the Brewer–Dobson Circulation, Including Its Extension to High LatitudesJournal of Climate, 22
-
W. Jones (1969)
Ray tracing for internal gravity wavesJournal of Geophysical Research, 74
-
R. Ford, M. McIntyre, W. Norton (2000)
Balance and the Slow Quasimanifold: Some Explicit ResultsJournal of the Atmospheric Sciences, 57
-
C. Garrett, W. Munk (1975)
Space-Time Scales of Internal Waves' A Progress ReportJournal of Geophysical Research, 80
-
E. Kalnay, M. Kanamitsu, R. Kistler, W. Collins, D. Deaven, L. Gandin, M. Iredell, S. Saha, G. White, J. Woollen, Yuejian Zhu, M. Chelliah, W. Ebisuzaki, W. Higgins, J. Janowiak, K. Mo, C. Ropelewski, Jiande Wang, A. Leetmaa, R. Reynolds, R. Jenne, Dennis Joseph (1996)
The NCEP/NCAR 40-Year Reanalysis ProjectRenewable Energy
-
P. Gaspar, Y. Gregoris, J. Lefèvre (1990)
A simple eddy kinetic energy model for simulations of the oceanic vertical mixing: Tests at Station Papa and long-term upper ocean study siteJournal of Geophysical Research, 95
-
K. Polzin (2008)
Mesoscale Eddy–Internal Wave Coupling. Part I: Symmetry, Wave Capture, and Results from the Mid-Ocean Dynamics ExperimentJournal of Physical Oceanography, 38
-
C. Bender, S. Orszag (1999)
Advanced mathematical methods for scientists and engineers I: asymptotic methods and perturbation theory. -
D. Olbers (1976)
Nonlinear energy transfer and the energy balance of the internal wave field in the deep oceanJournal of Fluid Mechanics, 74
-
E. Becker (2004)
Direct heating rates associated with gravity wave saturationJournal of Atmospheric and Solar-Terrestrial Physics, 66
-
C. McComas, P. Müller (1981)
Time Scales of Resonant Interactions Among Oceanic Internal WavesJournal of Physical Oceanography, 11
-
P. Williams, T. Haine, P. Read (2008)
Inertia–Gravity Waves Emitted from Balanced Flow: Observations, Properties, and ConsequencesJournal of the Atmospheric Sciences, 65
-
C. Warner, M. McIntyre (1996)
On the Propagation and Dissipation of Gravity Wave Spectra through a Realistic Middle AtmosphereJournal of the Atmospheric Sciences, 53
-
P. Preusse, S. Eckermann, M. Ern, J. Oberheide, R. Picard, R. Roble, M. Riese, J. Russell, M. Mlynczak (2009)
Global Ray Tracing Simulations of the SABER Gravity Wave ClimatologyJournal of Geophysical Research, 114
-
P. Lu, J. McCreary, Barry Klinger (1998)
Meridional Circulation Cells and the Source Waters of the Pacific Equatorial UndercurrentJournal of Physical Oceanography, 28
-
D. Olbers, C. Eden (2013)
A Global Model for the Diapycnal Diffusivity Induced by Internal Gravity WavesJournal of Physical Oceanography, 43
-
M. Alexander, M. Geller, C. McLandress, S. Polavarapu, P. Preusse, F. Sassi, Kaoru Sato, S. Eckermann, M. Ern, A. Hertzog, Y. Kawatani, M. Pulido, T. Shaw, M. Sigmond, R. Vincent, S. Watanabe (2010)
Recent developments in gravity‐wave effects in climate models and the global distribution of gravity‐wave momentum flux from observations and modelsQuarterly Journal of the Royal Meteorological Society, 136
-
C. Eden, D. Olbers (2014)
An energy compartment model for propagation, non-linear interaction and dissipation of internal gravity waves -
G. Egbert, S. Erofeeva, R. Ray (2009)
Assimilation of altimetry data for nonlinear shallow-water tides: Quarter-diurnal tides of the Northwest European ShelfContinental Shelf Research, 30
-
T. Osborn, C. Cox (1972)
Oceanic fine structureGeophysical and Astrophysical Fluid Dynamics, 3
-
M. Molemaker, J. McWilliams, I. Yavneh (2005)
Baroclinic Instability and Loss of BalanceJournal of Physical Oceanography, 35
-
T. McDougall (2003)
Potential Enthalpy: A Conservative Oceanic Variable for Evaluating Heat Content and Heat FluxesJournal of Physical Oceanography, 33
-
C. Eden, R. Greatbatch (2008)
Towards a mesoscale eddy closureOcean Modelling, 20
-
C. Garrett (2001)
What is the near-inertial band and why is it different from the rest of the internal wave spectrum?Journal of Physical Oceanography, 31
-
Walter Smith, D. Sandwell (1997)
Global Sea Floor Topography from Satellite Altimetry and Ship Depth SoundingsScience, 277
-
O. Bühler, M. McIntyre (2005)
Wave capture and wave–vortex dualityJournal of Fluid Mechanics, 534
-
M. Molemaker, J. McWilliams, X. Capet (2010)
Balanced and unbalanced routes to dissipation in an equilibrated Eady flowJournal of Fluid Mechanics, 654
-
K. Polzin, A. Garabato, T. Huussen, B. Sloyan, Stephanie Waterman (1995)
Finescale Parameterizations of Turbulent DissipationJournal of Geophysical Research, 119
- Publisher
- Springer International Publishing
- Copyright
- © Springer Nature Switzerland AG 2019
- ISBN
- 978-3-030-05703-9
- Pages
- 87 –125
- DOI
- 10.1007/978-3-030-05704-6_3
- Publisher site
- See Chapter on Publisher Site
Abstract
[The IDEMIX conceptIDEMIXconcept is an energetically consistent framework to describe wave effects in circulation models of ocean and atmosphere. It is based on the radiative transfer equation for an internal gravity wave field in physical and wavenumber space and was shown to be successful for ocean applications. An improved IDEMIX model for the ocean will be constructed and extended by a new high-frequency, high vertical wavenumber compartment, forcing by mesoscale eddy dissipation, anisotropic tidal forcing, and wave–mean flow interaction. It will be validated using observational and model estimates. A novel concept for gravity wave parameterization in atmospheric circulation models is developed. As for the ocean, the wave field is represented by the wave energy density in physical and wavenumber space, and its prognostic computation is performed by the radiative transfer equation. This new concept goes far beyond conventional gravity wave schemes which are based on the single-column approximation and, in particular, on the strong assumptions of a stationary mean flow and a stationary wave energy equation. The radiative transfer equation has—to our knowledge—never been considered in the atmospheric community as a framework for subgrid-scale parameterization. The proposed parameterization will, for the first time, (1) include all relevant sources continuously in space and time and (2) accommodate all gravity wave sources (orography, fronts, and convection) in a single parameterization framework. Moreover, the new scheme is formulated in a precisely energy-preserving fashion. The project will contribute to a transfer of knowledge from the oceanic community to the atmospheric community and vice versa. We give a brief description of the oceanic and atmospheric internal wave fields, the most important processes of generation and interactions, and the ingredients of the model IDEMIX.]
Published: Jan 24, 2019