Get 20M+ Full-Text Papers For Less Than $1.50/day. Start a 14-Day Trial for You or Your Team.

Learn More →

Reconstruction of Submesoscale Velocity Field from Surface Drifters

Reconstruction of Submesoscale Velocity Field from Surface Drifters AbstractThe extensive drifter deployment during the Lagrangian Submesoscale Experiment (LASER) provided observations of the surface velocity field in the northern Gulf of Mexico with high resolution in space and time. Here, we estimate the submesoscale velocity field sampled by those drifters using a procedure that statistically interpolates these data both spatially and temporally. Because the spacing of the drifters evolves with the flow, causing the resolution that they provide to vary in space and time, it is important to be able to characterize where and when the estimated velocity field is more or less accurate, which we do by providing fields of interpolation errors. Our interpolation uses a squared-exponential covariance function characterizing correlations in latitude, longitude, and time. Two novelties in our approach are 1) the use of two scales of variation per dimension in the covariance function and 2) allowing the data to determine these scales along with the appropriate amplitude of observational noise at these scales. We present the evolution of the reconstructed velocity field along with maps of relative vorticity, horizontal divergence, and lateral strain rate. The reconstructed velocity field exhibits horizontal length scales of 0.4–3.5 km and time scales of 0.6–3 h, and features with convergence up to 8 times the planetary vorticity f, lateral strain rate up to 10f, and relative vorticity up to 13f. Our results point to the existence of a vigorous and substantial ageostrophic circulation in the submesoscale range. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Journal of Physical Oceanography American Meteorological Society

Reconstruction of Submesoscale Velocity Field from Surface Drifters

Download PDF
18 pages

Loading next page...
 
/lp/american-meteorological-society/reconstruction-of-submesoscale-velocity-field-from-surface-drifters-GlMqpRp0Wh

References

References for this paper are not available at this time. We will be adding them shortly, thank you for your patience.

Publisher
American Meteorological Society
Copyright
Copyright © American Meteorological Society
ISSN
1520-0485
eISSN
1520-0485
DOI
10.1175/JPO-D-18-0025.1
Publisher site
See Article on Publisher Site

Abstract

AbstractThe extensive drifter deployment during the Lagrangian Submesoscale Experiment (LASER) provided observations of the surface velocity field in the northern Gulf of Mexico with high resolution in space and time. Here, we estimate the submesoscale velocity field sampled by those drifters using a procedure that statistically interpolates these data both spatially and temporally. Because the spacing of the drifters evolves with the flow, causing the resolution that they provide to vary in space and time, it is important to be able to characterize where and when the estimated velocity field is more or less accurate, which we do by providing fields of interpolation errors. Our interpolation uses a squared-exponential covariance function characterizing correlations in latitude, longitude, and time. Two novelties in our approach are 1) the use of two scales of variation per dimension in the covariance function and 2) allowing the data to determine these scales along with the appropriate amplitude of observational noise at these scales. We present the evolution of the reconstructed velocity field along with maps of relative vorticity, horizontal divergence, and lateral strain rate. The reconstructed velocity field exhibits horizontal length scales of 0.4–3.5 km and time scales of 0.6–3 h, and features with convergence up to 8 times the planetary vorticity f, lateral strain rate up to 10f, and relative vorticity up to 13f. Our results point to the existence of a vigorous and substantial ageostrophic circulation in the submesoscale range.

Journal

Journal of Physical OceanographyAmerican Meteorological Society

Published: Apr 6, 2019

References

  • Relative dispersion: Local and nonlocal dynamics
    Bennett, A. F.
  • Submesoscale evolution of surface drifter triads in the Gulf of Mexico
    Berta, M.; Griffa, A.; Özgökmen, T. M.; Poje, A. C.
  • A technique for objective analysis and design of oceanographic experiment applied to MODE-73
    Bretherton, F. P.; Davis, R. E.; Fandry, C. B.
  • A limited memory algorithm for bound constrained optimization
    Byrd, R. H.; Lu, P.; Nocedal, J.; Zhu, C.
  • Mesoscale to submesoscale transition in the California Current System. Part II: Frontal processes
    Capet, X.; McWilliams, J. C.; Molemaker, M. J.; Shchepetkin, F.
  • Analysis models for the estimation of oceanic fields
    Carter, E. F.; Robinson, A. R.
  • Geostrophic turbulence
    Charney, J. G.
  • Enhanced turbulence and energy dissipation at ocean fronts
    D’Asaro, E.; Lee, C.; Rainville, L.; Harcourt, R.; Thomas, L.
  • Ocean convergence and the dispersion of flotsam
    D’Asaro, E.
  • Drifter observations of coastal surface currents during CODE: The statistical and dynamical views
    Davis, R. E.
  • The shear, convergence, and thermohaline structure of a front
    Flament, P.; Armi, L.
  • The evolving structure of an upwelling filament
    Flament, P.; Armi, L.; Washburn, L.
  • Drogue-loss detection for surface drifters during the Lagrangian submesoscale experiment (laser)
    Haza, A.
  • An objective analysis of the POLYMODE local dynamics experiment. Part II: Streamfunction and potential vorticity fields during the intensive period
    Hua, B. L.; Mcwilliams, J. C.; Owens, W. B.
  • An overview of uncertainty quantification techniques with application to oceanic and oil-spill simulations
    Iskandarani, M.; Wang, S.; Srinivasan, A.; Carlisle Thacker, W.; Winokur, J.; Knio, O. M.
  • Predicting the output from a complex computer code when fast approximations are available
    Kennedy, M. C.; O’Hagan, A.
  • A method for optimal analysis of fields with spatially variable mean
    Le Traon, P. Y.
  • Mapping the oceanic mesoscale circulation: Validation of satellite altimetry using surface drifters
    Le Traon, P. Y.; Hernandez, F.
  • A multiscale variational data assimilation scheme: Formulation and illustration
    Li, Z.; McWilliams, J. C.; Ide, K.; Farrara, J. D.
  • An analysis of mechanisms for submesoscale vertical motion at ocean fronts
    Mahadevan, A.; Tandon, A.
  • Efficient objective analysis of dynamically heterogeneous and nonstationary fields via the parameter matrix
    Mariano, A. J.; Brown, O. B.
  • Maps from the Mid-Ocean Dynamics Experiment: Part I. Geostrophic streamfunction
    McWilliams, J. C.
  • Submesoscale currents in the ocean
    McWilliams, J. C.
  • 2010: Balanced and unbalanced routes to dissipation in an equilibrated Eady flow
    Molemaker, M. J.; McWilliams, J. C.; Capet, X.
  • Spirals on the sea
    Munk, W.; Armi, L.; Fischer, K.; Zachariasen, F.
  • A biodegradable surface drifter for ocean sampling on a massive scale
    Novelli, G.; Guigand, C. M.; Cousin, C.; Ryan, E. H.; Laxague, N. J.; Dai, H.; Haus, B. K.; Özgökmen, T. M.
  • Drifter observations of submesoscale flow kinematics in the coastal ocean
    Ohlmann, J. C.; Molemaker, M. J.; Baschek, B.; Holt, B.; Marmorino, G.; Smith, G.
  • On multi-scale dispersion under the influence of surface mixed layer instabilities and deep flows
    Özgökmen, T. M.; Poje, A. C.; Fischer, P. F.; Childs, H.; Krishnan, H.; Garth, C.; Haza, A. C.; Ryan, E.
  • Spatial modelling using a new class of nonstationary covariance functions
    Paciorek, C. J.; Schervish, M. J.
  • Submesoscale dispersion in the vicinity of the Deepwater Horizon spill
    Poje, A. C.
  • Intense deformation field at oceanic front inferred from directional sea surface roughness observations
    Rascle, N.; Molemaker, J.; Marié, L.; Nouguier, F.; Chapron, B.; Lund, B.; Mouche, A.
  • Statistics of vertical vorticity, divergence, and strain in a developed submesoscale turbulence field
    Shcherbina, A. Y.; D’Asaro, E. A.; Lee, C. M.; Klymak, J. M.; Molemaker, M. J.; McWilliams, J. C.
  • Pragmatic aspects of uncertainty propagation: A conceptual review
    Thacker, W. C.; Iskandarani, M.; Gonçalves, R. C.; Srinivasan, A.; Knio, O. M.
  • Intensification of ocean fronts by down-front winds
    Thomas, L. N.; Lee, C. M.
  • Friction, frontogenesis, and the stratification of the surface mixed layer
    Thomas, L. N.; Ferrari, R.
  • Mapping mesoscale currents by optimal interpolation of satellite radiometer and altimeter data
    Wilkin, J. L.; Bowen, M. M.; Emery, W. J.