Model and experiment setup The Navy Coastal Ocean Model (NCOM) is used for numerical simulation of the sea level response to tidal forcing. The NCOM is.

Slides:



Advertisements
Similar presentations
1 Internal waves and tidal energy dissipation observed by satellite altimetry E. Schrama, TU Delft / Geodesy The Netherlands
Advertisements

Tides Tide producing forces Semi-diurnal; diurnal tides
ISSUES IN PREDICTING SOLITARY WAVES IN STRAITS OF MESSINA AND LUZON A. Warn-Varnas, P. Smolarkiewicz, J. Hawkins, S. Piacsek, S. Chin-Bing, D. King and.
Numerical simulation of internal tides in the Sicily and Messina Straits Jihene Abdennadher and Moncef Boukthir Institut Preparatoire aux Etudes d’Ingenieur.
Factors modifying the framework established: Tides Atmospheric Forcing - wind, barometric pressure River Discharge Bathymetry Morphology.
Morphodynamic Equilibria in Tidal Embayments with Decreasing Cross-Section Henk Schuttelaars The Institute for Marine and Atmospheric research Utrecht.
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.
Coastal Ocean Dynamics Baltic Sea Research Warnemünde
The effect of ocean tides on a climate model simulation Ocean Modelling September, 2010 M. Müller, H. Haak, J.H. Jungclaus, J. Sündermann, M. Thomas Erik.
Benjamin A. Schenkel and Robert E. AMS Tropical Conference 2012 Department of Earth, Ocean, and Atmospheric Science.
Detecting and Tracking of Mesoscale Oceanic Features in the Miami Isopycnic Circulation Ocean Model. Ramprasad Balasubramanian, Amit Tandon*, Bin John,
Vertical Mixing Parameterizations and their effects on the skill of Baroclinic Tidal Modeling Robin Robertson Lamont-Doherty Earth Observatory of Columbia.
MODULATING FACTORS OF THE CLIMATOLOGICAL VARIABILITY OF THE MEXICAN PACIFIC; MODEL AND DATA. ABSTRACT. Sea Surface Temperature and wind from the Comprehensive.
Model Simulation Studies of Hurricane Isabel in Chesapeake Bay Jian Shen Virginia Institute of Marine Sciences College of William and Mary.
Juan Carlos Ortiz Royero Ph.D.
A Circulation Model to Investigate the Movement of Wastes from an Open Ocean Aquaculture Site David W. Fredriksson U. S. Naval Academy NOAA Research -
Lien, R.-C., and M. C. Gregg (2001), Observations of turbulence in a tidal beam and across a coastal ridge, J. Geophys. Res., 106,
An Assimilating Tidal Model for the Bering Sea Mike Foreman, Josef Cherniawsky, Patrick Cummins Institute of Ocean Sciences, Sidney BC, Canada Outline:
Internal Tides in the Weddell-Scotia Confluence Region, Antarctica Susan L. Howard, Laurence Padman, and Robin D. Muench Introduction Recent observations,
Extratropical Storm-Induced Coastal Inundation: Scituate, MA Robert C. Beardsley 1, Changsheng Chen 2, Qichun Xu 2, Jianhua Qi 2, Huichan Lin 2 2 School.
OEAS 604 Introduction to Physical Oceanography Eileen Hofmann John Klinck Chet Grosch.
Diurnal Water and Energy Cycles over the Continental United States Alex Ruane John Roads Scripps Institution of Oceanography / UCSD February 27 th, 2006.
Oceanic and Atmospheric Modeling of the Big Bend Region Steven L. Morey, Dmitry S. Dukhovksoy, Donald Van Dyke, and Eric P. Chassignet Center for Ocean.
1.Introduction 2.Description of model 3.Experimental design 4.Ocean ciruculation on an aquaplanet represented in the model depth latitude depth latitude.
Tidal Energy Extraction in an Idealized Ocean- Fjord Tidal Model with Astronomical Forcing EWTEC 2013, Aalborg, Denmark, September 2012 Mitsuhiro Kawase.
IMPROVEMENT OF GLOBAL OCEAN TIDE MODELS IN SHALLOW WATER REGIONS Altimetry for Oceans and Hydrology OST-ST Meeting Poster Number: SV Yongcun Cheng,
Resolution (degree) and RMSE (cm) Resolution (degree) and RMSE (cm)
OCEN 201 Introduction to Ocean & Coastal Engineering Ocean Environment &Waves Jun Zhang
Impact of partial steps and momentum advection schemes in a global ocean circulation model at eddy-premitting resolution Barnier Bernard et al.
Downscaling Future Climate Scenarios for the North Sea 2006 ROMS/TOMS Workshop, Alcalá de Henares, 6-8 November Bjørn Ådlandsvik Institute of Marine Research.
USF FVCOM Tropical Cyclone Inundation Testbed Progress by Robert H. Weisberg, Lianyuan Zheng and Yong Huang College of Marine Science University of South.
Modeling the upper ocean response to Hurricane Igor Zhimin Ma 1, Guoqi Han 2, Brad deYoung 1 1 Memorial University 2 Fisheries and Oceans Canada.
Sensitivity Studies Using Nested HYCOM Models 2004 Layered Ocean Model Users’ Workshop February 9-11, 2004 RSMAS, Miami, FL Patrick Hogan Luis Zamudio.
Diurnal Water and Energy Cycles over the Continental United States Alex Ruane John Roads Scripps Institution of Oceanography / UCSD April 28 th, 2006 This.
TIDES Tide - generic term to define alternating rise and fall in sea level with respect to land and is produced by the balance between the gravitational.
Internal Tide Generation Over a Continental Shelf Summer 2008 internship Gaёlle Faivre Flavien Gouillon, Alexandra Bozec Pr. Eric P. Chassignet.
GP33A-06 / Fall AGU Meeting, San Francisco, December 2004 Magnetic signals generated by the ocean circulation and their variability. Manoj,
Impact of Power Extraction on the Florida Current/Gulf Stream System: New Results Alexandra Bozec 1, Eric Chassignet 1, Howard P. Hanson 2 1 Center for.
Enhancing predictability of the Loop Current variability using Gulf of Mexico Hycom Matthieu Le Hénaff (1) Villy Kourafalou (1) Ashwanth Srinivasan (1)
Ensemble-based Assimilation of HF-Radar Surface Currents in a West Florida Shelf ROMS Nested into HYCOM and filtering of spurious surface gravity waves.
Over the northern West Florida Shelf several reef fish species (with gag grouper being a key species) spawn near the outer shelf edge in winter and early.
Lecture 6: Open Boundaries Solid wall Open boundary Let us first consider the ocean is incompressible, which satisfies (6.1) H  Integrating (6.1) from.
Hindcast Simulations of Hydrodynamics in the Northern Gulf of Mexico Using the FVCOM Model Zizang Yang 1, Eugene Wei 1, Aijun Zhang 2, Richard Patchen.
1. The text book reading assignment that corresponds with this pwr pt is Trujillo and Thurman chapter 8 pp
Standing Waves and Resonance Standing Wave: “Standing waves” are formed from two or more traveling waves that collide and are “in tune” with one another.
Table 1. Characteristics of baroclinic topographic wave simulated in the model Dmitry Dukhovskoy, Steven Morey, James O’Brien Center for Ocean-Atmospheric.
Internal tides Seim, Edwards, Shay, Werner Some background SAB – generation site? Shelf observations Towards a climatology?
Joint OS & SWH meeting in support of Wide-Swath Altimetry Measurements Washington D.C. – October 30th, 2006 Baptiste MOURRE ICM – Barcelona (Spain) Pierre.
Naeko Takahashi Qing Wang Scott C. Hagen, Ph.D., P.E. Astronomic Tides, Flows and Hurricane Storm Surge Modeling of the Pascagoula River, MS March 4, 2009.
Evaluation of two global HYCOM 1/12º hindcasts in the Mediterranean Sea Cedric Sommen 1, Alexandra Bozec 2, Eric P. Chassignet 2 Experiments Transport.
Assessing the Influence of Decadal Climate Variability and Climate Change on Snowpacks in the Pacific Northwest JISAO/SMA Climate Impacts Group and the.
Assessment of a wetting and drying scheme in the HYbrid Coordinate Ocean Model (HYCOM) Sébastien DENNEULIN Eric Chassignet, Flavien Gouillon, Alexandra.
Assessment of a wetting and drying scheme in the HYbrid Coordinate Ocean Model (HYCOM) Sébastien DENNEULIN Summer 2007 Internship at COAPS Eric Chassignet,
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)
02-04 Feb.2016Workshop on Development of the Red Sea Environment & Fisheries 1 Sea Level Variations along the Red Sea Coasts Tarek M. El-Geziry (PhD) Researcher.
RTOFS Monitoring and Evaluation Metrics Avichal Mehra MMAB/EMC/NCEP/NWS.
When 0.25 < F < 1.25 the tide is mixed - mainly semidiurnal
Philip Hall Proudman Oceanographic Laboratory Liverpool
Bruce Cornuelle, Josh Willis, Dean Roemmich
Enhancement of Wind Stress and Hurricane Waves Simulation
Importance of high-resolution modeling for storm surge, hurricane waves, coastal water levels, and currents in Puerto Rico and the U.S. Virgin Islands.
Tidal Energy Extraction
Peter Brandt (1), Martin Claus (1), Richard J
Shelf-basin exchange in the Western Arctic Ocean
Robert K. Forney, Hugh Roarty, Scott Glenn March 5th, 2015
When 0.25 < F < 1.25 the tide is mixed - mainly semidiurnal
Effects of Temperature and Precipitation Variability on Snowpack Trends in the Western U.S. JISAO/SMA Climate Impacts Group and the Department of Civil.
Wind Stress and Ekman Mass Transport along CalCOFI lines: 67,70 and 77 by Lora Egley
  Robin Robertson Lamont-Doherty Earth Observatory
Ramtin Sabeti (1) and Mohammad Heidarzadeh (2)
Presentation transcript:

Model and experiment setup The Navy Coastal Ocean Model (NCOM) is used for numerical simulation of the sea level response to tidal forcing. The NCOM is a three-dimensional ocean model but In these simulations, it is run as a barotropic ocean model. The model domain is shown in Figure 1. The horizontal resolution is 1/60°. The model Open Boundaries (OB) are the Straits of Florida and the Caribbean Sea (Figure 1). Flather [1976] OB conditions are applied. The basin is initially at rest and there is no forcing but tides. Only the main four tidal constituents are considered (M 2, S 2, O 1, K 1 ) in this study as they represent 90% of the total tidal bulk [He and Weisberg, 2002]. Only M 2 and O 1 are shown here. Three model experiments are performed: 1) Model forced by a local tidal potential given by equation (1) and derived from Newton’s tidal theory (LTP experiment) (1) 2) Model forced only at OB by tidal barotropic transport and velocities derived from the western Atlantic ADCIRC model [Mukai et al, 2002] (OB experiment) 3) Both forcing mechanisms are combined (LTP&OB experiment) Figure 1: Model domain and tidal gauges Forced Tidal Response in the Gulf of Mexico Motivation Examination of the role of the astronomical forcing in governing the behavior of the tides and new tidal energetic estimates in the Gulf of Mexico Introduction The present study employs a non-assimilative numerical ocean model to understand the nature of tides in the Gulf of Mexico (GoM). A set of numerical experiments is conducted to yield new understanding of the tidal response due to a local tidal potential, tidal signal propagation coming from the Atlantic by considering forcing at the model open boundaries, and the modification of the propagating signal by combining both model forcing mechanisms. Comparison of the model results with observations and previous studies is conducted and new estimates of total tidal power and tidal energy fluxes for semidiurnal and diurnal constituents are produced from the model. Flavien Gouillon 1, Steven Morey 1, Dmitry Dukhovskoy 1, James J. O’Brien 1, 1 Center for Ocean-Atmospheric Predictions Studies, Florida State University, Tallahassee, FL, USA Conclusion The LTP forcing alters the tidal signal propagating from the model OB especially for the semidiurnal constituent. The astronomical forcing needs to be taken into account for high resolution numerical studies of the GoM. A careful tidal energetic study provides new estimates of tidal power and tidal dissipation rates within the GoM and confirms that the GoM is acting as a major sink for both semidiurnal as well as diurnal tidal energy. Tidal EnergeticsTidal amplitudes and phases Figure 2: Tidal amplitudes in meters (contoured) and phases in degrees (colored) for all tidal constituents. OB experiment is left panel and LTP&OB is right panel. Figure 3: Comparison of tidal phasesFigure 4: Comparison of tidal amplitudes The sea surface elevation time series from each model experiment is analyzed using the T-Tide [Pawlowiscz et al, 2002] harmonic analysis utility to extract estimates of the phases and amplitude. Resulting maps are shown in Figure 2. Results for semidiurnal constituents are describe in part a) and diurnal constituents description are in part b). Figure 3 and 4 compare amplitudes and phases to observations from the tidal gauges shown in Figure 1. a) The LTP&OB experiment (Figure 2a) shows a good agreement with previous studies. For the semidiurnal constituent the amphidromic point is north of the Yucatan Peninsula (YP). The co-tidal lines become compacted in the central GoM, roughly following a line from the U.S. Gulf Coast to the YP. This is where the tidal pattern changes to become predominantly diurnal. The maximal tidal amplitudes are found in the wide shelves due to resonance phenomena [Clarke, 1995]. Considering only the OB forcing (Figure 2b), the amphidromic point is slightly shifted to the northeast and the tidal wave is traveling faster. b) The LTP&OB experiment for the diurnal experiment (Figure 2c) shows that phases are very uniform into the basin. Both entrances are at the same phase which show the co-oscillating phenomena. Combining the LTP forcing does not change the behavior of the diurnal tides (Figure 2d) except a slight decrease on the overall amplitude which will have an impact on the total diurnal tidal energy in the basin. A set of new numerical experiments is run to calculate tidal energy density maps, tidal power and energy fluxes for M 2 and O 1. Figure 5 shows the sum of the kinetic and potential energy per unit area, averaged over the tidal constituent period. Prominent features include an area of weak energy spatially corresponding with the amphidrome, which naturally has a zero elevation through time. The maximum energy is found to be at the shelf and confirms the tidal shelf amplification theory. Contours show that the two forcing mechanisms work constructively together to increase the tidal signal in some regions as well as destructively interfering to decrease the tidal elevation in other area. For O1, the energy density map is spatially uniform due mainly to the co-oscillating phenomena. Table 1 gives the M 2 and O 1 tidal power within the Gulf for each experiments. Energy fluxes are computed according to Kowalik [1993] and are given by (2) These fluxes are shown in Figure 6. The net tidal energy dissipation and their comparison with previous studies are given by the Table 2 Figure 5: Total energy density maps (colored on a logarithmic scale, units are J.m -2 ). Contours are the ratios of the tidal energy density for the LTP (black solid line) and OB (gray dashed line) over the tidal energy density of the LTP&OB experiment for M 2 (left panel) and O 1 (right panel). Table 1: Tidal power in GWTable 2: Net tidal energy dissipation in GW Figure 6: Energy fluxes in the GoM b) d) Clarke, Allan J., (1995), Northeastern Gulf of Mexico physical oceanography workshop; 417 proceedings of a workshop held in Tallahassee, Florida, April 5-7, Prepared by 418 Florida State University. OCS Study MMS U.S. Department of the Interior, 419 Minerals Management Services, Gulf of Mexico OCS Region, New Orleans, La pp. Flather, R.A., (1976), A tidal model of the northwest European continental shelf. 425 Memoires de la societe Royale de Liege 6 (10), Gouillon F., S. M. Morey, D. S. Dukhovskoy, J.J. O’Brien (2007), Forced Tidal response in the Gulf of Mexico, Journ. Geophys. Res, In Review.