Eddy activity in the California Current System:

Slides:

Advertisements

Similar presentations

Numerical simulation of internal tides in the Sicily and Messina Straits Jihene Abdennadher and Moncef Boukthir Institut Preparatoire aux Etudes d’Ingenieur.

Advertisements

ROMS effective resolution

L. K. Shay, J. Martinez-Pedraja , A. B. Parks

Internal tide energetics in the Sicilian Strait and Adjacent areas Jihène Abdennadher and Moncef Boukthir UR1304, Institut Préparatoire aux Etudes d’Ingénieur.

Preliminary results on Formation and variability of North Atlantic sea surface salinity maximum in a global GCM Tangdong Qu International Pacific Research.

Working Group 4 Coastal Biogeochemistry Forum, June 23-25, 2004 K. Lindsay, G. McKinley, C. Nevison, K. Plattner, R. Seifert Can coastal ecosystems be.

Modeling the M 2 and O 1 Barotropic and Baroclinic Tides in the Gulf of Mexico Using the HYbrid Coordinate Ocean Model (HYCOM) Flavien Gouillon 1 ; B.

Experiment Design: Validation: Ocean mesoscale variability was estimated on eddy kinetic energy (EKE), calculated from TOPEX/ Poseidon, ERS-1/-2 and Jason.

Low frequency variability of the CCS: effect of the El Nino. X. Capet, J McWilliams, A. Shchepetkin (UCLA) Eastern Pacific Ocean Conference 2004.

Quantitative Description of Particle Dispersal over Irregular Coastlines Tim Chaffey, Satoshi Mitarai, Dave Siegel.

Why do we have storms in atmosphere?. Mid-atmosphere (500 hPa) DJF temperature map What are the features of the mean state on which storms grow?

CCS dynamics: sensitivity to wind forcing, heat flux and boundary conditions Roms workshop, 2003 X. Capet, P. Penven, P. Marchesiello, J. McWilliams UCLA.

Baroclinic Instability in the Denmark Strait Overflow and how it applies the material learned in this GFD course Emily Harrison James Mueller December.

The transition from mesoscale to submesoscale in the California Current System X. Capet, J. McWilliams, J. Molemaker, A. Shchepetkin (IGPP/UCLA), feb.

Average circulation, seasonal cycle and mesoscale dynamics of the Peru Current System: A modeling approach Pierrick Penven (IRD), Vincent Echevin (IRD),

Mixing & Turbulence Mixing leads to a homogenization of water mass properties Mixing occurs on all scales in ocean molecular scales (10’s of mm) basin.

Submesoscale secondary instability in an upwelling system: mechanisms and implications for upper ocean dynamics X. Capet, J. McWilliams, J. Molemaker,

ROMS modeling of stormwater plumes and anthropogenic nitrogen inputs in the SCB Eileen Idica PhD candidate, Dept Civil &

COLLABORATORS: P. Estrade, S. Herbette, C. Lett, A. Peliz, C. Roy, B. Sow, C. Roy EDDY-DRIVEN DISPERSION IN COASTAL UPWELLING SYSTEMS California Canary.

SIO 210: Eddies and mixing L. Talley Fall, 2014

ROLE OF IRREGULAR COASTLINES IN LARVAL DISPERSAL Tim Chaffey, Satoshi Mitarai, Dave Siegel Results and research plan.

MODULATING FACTORS OF THE CLIMATOLOGICAL VARIABILITY OF THE MEXICAN PACIFIC; MODEL AND DATA. ABSTRACT. Sea Surface Temperature and wind from the Comprehensive.

Mixing & Turbulence Mixing leads to a homogenization of water mass properties Mixing occurs on all scales in ocean –molecular scales (10’s of  m) –basin.

II. Synoptic Atmospheric Destabilization Processes Elevated Mixed Layer (EML) Synoptic Lifting Dynamic Destabilization Differential Advection.

Effects of Ocean-Atmosphere Coupling in a Modeling Study of Coastal Upwelling in the Area of Orographically-Intensified Flow Natalie Perlin, Eric Skyllingstad,

Submesoscale for dummies: a journey in the world of frontal kilometer scale turbulence X. Capet J. McWilliams, J. Molemaker, A. Shchepetkin (UCLA)‏ P.

Sea Ice Deformation Studies and Model Development

“ Combining Ocean Velocity Observations and Altimeter Data for OGCM Verification ” Peter Niiler Scripps Institution of Oceanography with original material.

1.Introduction 2.Description of model 3.Experimental design 4.Ocean ciruculation on an aquaplanet represented in the model depth latitude depth latitude.

Sara Vieira Committee members: Dr. Peter Webster

Mapping Ocean Surface Topography With a Synthetic-Aperture Interferometry Radar: A Global Hydrosphere Mapper Lee-Lueng Fu Jet Propulsion Laboratory Pasadena,

Southern California Coast Observed Temperature Anomalies Observed Salinity Anomalies Geostrophic Along-shore Currents Warming Trend Low Frequency Salinity.

Regional Air-Sea Interactions in Eastern Pacific 6th International RSM Workshop Palisades, New York July 11-15, th International RSM Workshop Palisades,

Toward a mesoscale flux inversion in the 2005 CarboEurope Regional Experiment T.Lauvaux, C. Sarrat, F. Chevallier, P. Ciais, M. Uliasz, A. S. Denning,

Abstract – The Alaska Coastal Current (ACC) is located in a region with prevailing downwelling favorable winds, flows over a long stretch of coastline.

The Linear and Non-linear Evolution Mechanism of Mesoscale Vortex Disturbances in Winter Over Western Japan Sea Yasumitsu MAEJIMA and Keita IGA (Ocean.

“Very high resolution global ocean and Arctic ocean-ice models being developed for climate study” by Albert Semtner Extremely high resolution is required.

1) What is the variability in eddy currents and the resulting impact on global climate and weather? Resolving meso-scale and sub- meso-scale ocean dynamics.

Analysis of four decadal simulations of the Skagerrak mesoscale circulation using two ocean models Lars Petter Røed 1 and Jon Albretsen 2 Presented at.

Modeling the Gulf of Alaska using the ROMS three-dimensional ocean circulation model Yi Chao 1,2,3, John D. Farrara 2, Zhijin Li 1,2, Xiaochun Wang 2,

Impact of wind-surface current covariability on the Tropical Instability Waves Tropical Atlantic Meeting Paris, France October 18, 2006 Tropical Atlantic.

1 Development of a Regional Coupled Ocean-Atmosphere Model Hyodae Seo, Arthur J. Miller, John O. Roads, and Masao Kanamitsu Scripps Institution of Oceanography.

One float case study The Argo float ( ) floating in the middle region of Indian Ocean was chosen for this study. In Figure 5, the MLD (red line),

Inertia-Gravity waves and their role in mixing Geraint Vaughan University of Manchester, UK.

Permanent Meanders in the California Current System and Comparison of Near- Surface Observations with OGCM Solutions Luca Centurioni (SIO-PORD) Collaborators:

Numerical Investigation of Air- Sea Interactions During Winter Extratropical Storms Presented by Jill Nelson M.S. Marine Science Candidate Graduate Research.

Model Forced by: NCEP winds only Model Forced by: NCEP winds Local Surface Heat Flux Mean Advection of T’ CalCOFI Observations Coastal.

Filling the Gap: The Structure of Near Coastal Winds Jeroen Molemaker, Francois Colas and Xavier Capet University of California Los Angeles.

The California Current System from a Lagrangian Perspective Carter Ohlmann Institute for Computational Earth System Science, University of California,

Wind-SST Coupling in the Coastal Upwelling --- An Empirical Numerical Simulation X. Jin, C. Dong, and J. C. McWilliams (IGPP/UCLA) D. B. Chelton (COAS/OSU)

Interannual to decadal variability of circulation in the northern Japan/East Sea, Dmitry Stepanov 1, Victoriia Stepanova 1 and Anatoly Gusev.

Coastal Oceanography Outline Global coastal ocean Dynamics Western boundary current systems Eastern boundary current systems Polar ocean boundaries Semi-enclosed.

Page 1© Crown copyright 2006 Boundary layer mechanisms in extra-tropical cyclones Bob Beare.

SPURS Synthesis Research Objectives: Budget calculations Resolve important terms of the freshwater and heat budgets of the upper 1000 m on temporal scales.

On the role of eddies for coastal productivity and carbon cycling Hartmut Frenzel 1, Nicolas Gruber 2,1, Gian-Kasper Plattner 2, Takeyoshi Nagai 3,1, James.

Jennifer Catto Supervisors: Len Shaffrey and Kevin Hodges Extra-tropical cyclones and Storm Tracks.

ROMS Embedded Gridding, Test and Application for the Simulation of the Central Upwelling of the Pacific Coast of the United States Contributors: James.

Matthew J. Hoffman CEAFM/Burgers Symposium May 8, 2009 Johns Hopkins University Courtesy NOAA/AVHRR Courtesy NASA Earth Observatory.

THE BC SHELF ROMS MODEL THE BC SHELF ROMS MODEL Diane Masson, Isaak Fain, Mike Foreman Institute of Ocean Sciences Fisheries and Oceans, Canada The Canadian.

Large Eddy Simulations of Entrainment and Inversion Structure Alison Fowler (MRes Physics of Earth and Atmosphere) Supervisor: Ian Brooks Entrainment Zone.

Seasonal Variations of MOC in the South Atlantic from Observations and Numerical Models Shenfu Dong CIMAS, University of Miami, and NOAA/AOML Coauthors:

Horizontal density structure and restratification

Dynamics of the Norwegian Atlantic Current from high resolution modeling Marie-Noëlle Houssais Christophe Herbaut, Antoine Martin, Dorotea Iovino, Anne-Cécile.

Intercomparison of ocean circulation in regional Arctic Ocean models at increasing spatial resolution – Preliminary Results Robert Osinski, Wieslaw Maslowski.

Dense Filaments, Turbulence, and Frontogenesis in the

Influence of mesoscale on larger scales mean state and variability and other layman thoughts... Thierry Huck, Olivier Arzel, Quentin Jamet Laboratoire.

Mark A. Bourassa and Qi Shi

Baroclinic and barotropic annular modes

Robin Robertson Lamont-Doherty Earth Observatory

Presentation transcript:

Eddy activity in the California Current System: patterns and variability of the potential to kinetic energy conversion, underlying processes. Comparison with the Humboldt system X. Capet, J. McWilliams, F. Colas ROMS meeting 2007, Los Angeles

Potential to eddy kinetic energy conversion term: <w'b'> <.> is some appropriate averaging operator. Unless otherwise stated it is a long term (10 years) time average with the seasonal cycle removed. An important quantity !!! 2 ways to compute <w'b'> from model fields. (1) or (2) and then multiply by b Both are roughly equivalent after all (ie there are no bugs in computation of w from (1). Forget my abstract !!!

Configurations: more idealized more realistic 5 ICC grids at various horizontal resolutions (12km, 6km, 3km, 1.5km, 750m). 720 x 720 km. 40 vertical levels, flat bottom, straight coastline. Boundary conditions are provided from 12km idealized USWC outputs (5 days averages). Atmospheric forcing spatially smooth and fixed in time (July COADS climatology) USWC 5km resolution, 32 levels with realistic bathymetry and coastline. Climatological forcings (QuikSCAT + COADS heat and freshwater fluxes). BCs from SODA climatology. Offline coupling: boundary conditions updated every 5 days.

EKE patterns in the CCS ROMS USWC 5km Altimetry Clear offshore EKE maximum along California, ie., away from the unstable coastal jet region.

Explanation for the offshore maximum ? <w'b'> patterns in the CCS Offshore propagation of eddy activity with inverse cascade offshore EKE sources (already in Marchesiello et al,2003) annual mean <w'b'> averaged from 0 to 200m The nearshore does not stand out in terms of energy conversion. same as left panel longshore averaged between 34.5 and 41.5o N cross-shore distance [km] -400 -200

<w'b'> patterns in the CCS There is also offshore propagation of the EKE sources (<w'b'>), which further highlights the intricate relationship between (seasonal) mean circulation and eddy activity. depth-integrated (0 to 200m) and longshore-averaged (34.5 to 41.5o N) <w'b'> spring summer fall winter cross-shore distance [km] -400 -200 cross-shore distance [km] -400 -200

Alongshore-averaged structure of <w'b'> Annual mean longshore-averaged (34.5 to 41.5o N) <w'b'> x-z section of <w'b'> reveals three types of processes that release available potential energy: Baroclinic instability of the coastal jet Baroclinic instability of the CCS Boundary layer (BL) buoyancy flux (BL restratification tendency)

buoyancy and associated w in a CCS 750m horizontal resolution Near surface <w'b'> : ageostrophic secondary circulations associated with submesoscale fronts buoyancy and associated w in a CCS 750m horizontal resolution solution. w is downward on the cold side, upward on the warm side b W x [km] Submesoscale is not resolved at 5km horizontal resolution. However the same mechanism of restratification by ASCs around fronts is present. Because of larger dissipation/diffusion, front intensification is much reduced and so are wrms and <w'b'>

Near surface <w'b'> : Mixed-layer baroclinic instability ualong u'along uacross u'across w w' Submesoscale instability growth is overwhelmingly due to w'b'. Its length scale is coherent with a “mixed layer deformation radius (Boccaletti et al, 2007). In the CCS submesoscale instability starts showing up around 2.5km horizontal resolution.

Near surface <w'b'> spatial/temporal modulations. <w'b'> averaged from 0 to 50m Signal tends to follow the offshore propagation of the mesoscale (the mesoscale strain is important and so is the mean position of the density front) spring summer vertical vorticity fall winter max and widespread in winter when air-sea fluxes are least stabilizing (or even destabilizing in southern part of the domain) and hbl is deepest (consistent with Fox-Kemper et al (2007), ie., a restratification by secondary circulations scaling as h2bl)

Near surface <w'b'> : where does it go ? Ten-fold increase of near surface <w'b'> between 10 and 1km horizontal resolution. However eddy kinetic energy itself is only moderately affected because the injection takes place in the submesoscale range, ie., within or close to the dissipation range. At resolution around 2-3km a forward cascade of KE shows up to connect the KE source (<w'b'> at submesoscale) and the sink (dissipation at somewhat higher wavenumber). eke injection eke dissipation dx=750m cascade dx=1.5km dx=3km 600km 60km 6km

EKE patterns in the Humboldt system ROMS 5km Altimetry ROMS patterns ok although 20 to 30% overestimate. Offshore EKE maximum as in California, ie., away from the unstable coastal jet region.

<w'b'> patterns in the Humboldt Current System annual mean <w'b'> averaged from 0 to 200m Clear maximum at the coast, ie., baroclinic instability of the coastal jet. Offshore patches of positive <w'b'> consistent with regions of max EKE EKE ROMS 5km

Coastal jet instability in the Humboldt versus CCS Annual mean longshore-averaged (34.5 to 41.5o N) <w'b'> Annual mean longshore-averaged (-32 to -26o N) <w'b'> Humboldt CCS Annual mean longshore velocity Annual mean longshore velocity (with minus sign) The vertical shear is stronger and extends deeper in the Humboldt.

Conclusions: Potential to kinetic energy conversion term was computed for the California and Humboldt systems. Time scales for replenishment of upper ocean (say, 0 to 500m) EKE deduced from <w'b'> are less than 100 days, ie., <w'b'> is a key term in the EKE budget (and <w'b'> distribution does correlate with that of the EKE). Several processes interacting with each other explain the <w'b'>: baroclinic instability of the coastal jet, the offshore mean currents and ageostrophic circulations near fronts (possibly related to submesoscale instabilities). Important differences between California and Humboldt a priori related to the velocity structure of the coastal jet. Sorry for not being with you. Enjoy the wine for me !!

A ROMS meeting in Brazil (eg A ROMS meeting in Brazil (eg., Arraial de Cabo, 2 hours drive from Rio) ?? US citizens may need a visa !!!