One float case study The Argo float (5900579) floating in the middle region of Indian Ocean was chosen for this study. In Figure 5, the MLD (red line),

Slides:

Advertisements

Similar presentations

Application of the ARGO and TAO data in improving the subsurface entrainment temperature parameterization for the Zebiak-Cane Ocean model Yonghong Yin*

Advertisements

A thermodynamic model for estimating sea and lake ice thickness with optical satellite data Student presentation for GGS656 Sanmei Li April 17, 2012.

Abstract We quantified turbulent dissipation in the Raritan river using both conventional methods and a novel technique, the structure function method.

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

C. A. Collins 1, R. Castro Valdez 2, A.S. Mascarenhas 2, and T. Margolina 1 Correspondence: Curtis A. Collins, Department of Oceanography, Naval Postgraduate.

THE PARAMETERIZATION OF STABLE BOUNDARY LAYERS BASED ON CASES-99 Zbigniew Sorbjan Marquette University, Milwaukee Zbigniew Sorbjan Marquette University,

Useful texts: Mann & Lazier, The Dynamics of Marine Ecosystems, Blackwell Science. Simpson, In: The Sea, vol 10, chapter 5. Simpson, In: The Sea, vol 11,

What drives the oceanic circulation ? Thermohaline driven Wind driven.

Argo Products at the Asia-Pacific Data-Research Center Konstantin Lebedev, Sharon DeCarlo, Peter Hacker, Nikolai Maximenko, James Potemra, Yingshuo Shen.

Clines Cline means ‘rapid change in’ Thermocline is a rapid change in temperature Pycnocline is a rapid change in density.

What drives the oceanic circulation ? Thermohaline driven (-> exercise) Wind driven (-> Sverdrup, Ekman)

Detecting and Tracking of Mesoscale Oceanic Features in the Miami Isopycnic Circulation Ocean Model. Ramprasad Balasubramanian, Amit Tandon*, Bin John,

Observational evidence for propagation of decadal spiciness anomalies in the North Pacific Yoshi N. Sasaki, N. Schneider, N. Maximenko, and K. Lebedev.

=(S,,0); 4=(S,,4000).

Estimation of the Barrier Layer Thickness in the Indian Ocean using satellite derived salinity Subrahmanyam Bulusu Satellite Oceanography Laboratory Department.

Estuarine Variability  Tidal  Subtidal Wind and Atmospheric Pressure  Fortnightly M 2 and S 2  Monthly M 2 and N 2  Seasonal (River Discharge)

Climate Change Projections of the Tasman Sea from an Ocean Eddy- resolving Model – the importance of eddies Richard Matear, Matt Chamberlain, Chaojiao.

Modeling Study of Frontal Variability in Drake Passage Bin Zhang 1 and John M Klinck 2 Model Description Regional Ocean Modeling System (ROMS) Dimensions:

Sustained Ocean Observations in Support of Sea Surface Salinity Process Studies Gustavo Jorge Goni National Oceanic and Atmospheric.

“ New Ocean Circulation Patterns from Combined Drifter and Satellite Data ” Peter Niiler Scripps Institution of Oceanography with original material from.

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

Regional Feedbacks Between the Ocean and the Atmosphere in the North Atlantic (A21D-0083) LuAnne Thompson 1, Maylis Garcia, Kathryn A. Kelly 1, James Booth.

Model LSW formation rate (2 yr averages) estimated from: (red) CFC-12 inventories, (black) mixed layer depth and (green) volume transport residual. Also.

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

EFFECTS OF OCEAN MIXING ON HURRICANE HEAT CONTENT ESTIMATES: A NUMERICAL STUDY S. DANIEL JACOB and LYNN K. SHAY Meteorology and Physical Oceanography Rosenstiel.

Turbulent properties: - vary chaotically in time around a mean value - exhibit a wide, continuous range of scale variations - cascade energy from large.

Sophie RICCI CALTECH/JPL Post-doc Advisor : Ichiro Fukumori The diabatic errors in the formulation of the data assimilation Kalman Filter/Smoother system.

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

Three Lectures on Tropical Cyclones Kerry Emanuel Massachusetts Institute of Technology Spring School on Fluid Mechanics of Environmental Hazards.

Monitoring Heat Transport Changes using Expendable Bathythermographs Molly Baringer and Silvia Garzoli NOAA, AOML What are time/space scales of climate.

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.

Mean Flow and Variability at the Intermediate depth in the southwestern East/Japan Sea with ARGO Floats Homan Lee, Tae-Hee Kim, Ji-Ho Kim, Jang-Won Seo,

Ventilation of the Equatorial Atlantic P. Brandt, R. J. Greatbatch, M. Claus, S.-H. Didwischus, J. Hahn GEOMAR Helmholtz Centre for Ocean Research Kiel.

An example of vertical profiles of temperature, salinity and density.

Camp et al. (2003) illustrated that two leading modes of tropical total ozone variability exhibit structrures of the QBO and the solar cycle. Figure (1)

Investigation of Mixed Layer Depth in the Southern Ocean by using a 1-D mixed layer model Chin-Ying Chien & Kevin Speer Geophysical Fluid Dynamics Institute,

Graduate Course: Advanced Remote Sensing Data Analysis and Application A COMPARISON OF LATENT HEAT FLUXES OVER GLOBAL OCEANS FOR FOUR FLUX PRODUCTS Shu-Hsien.

Typical Distributions of Water Characteristics in the Oceans.

 one-way nested Western Atlantic-Gulf of Mexico-Caribbean Sea regional domain (with data assimilation of SSH and SST prior to hurricane simulations) 

The Character of North Atlantic Subtropical Mode Water Potential Vorticity Forcing Otmar Olsina, William Dewar Dept. of Oceanography, Florida State University.

Geopotential and isobaric surfaces

Class 8. Oceans Figure: Ocean Depth (mean = 3.7 km)

A signal in the energy due to planetary wave reflection in the upper stratosphere J. M. Castanheira(1), M. Liberato(2), C. DaCamara(3) and J. M. P. Silvestre(1)

Estimating Vertical Eddy Viscosity in the Pacific Equatorial Undercurrent Natalia Stefanova Masters Thesis Defense October 31, 2008 UW School of Oceanography.

Lab 5 Physical and Chemical Properties of Sea Water

Assimilation of Sea Ice Concentration Observations in a Coupled Ocean-Sea Ice Model using the Adjoint Method.

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

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

Forces and accelerations in a fluid: (a) acceleration, (b) advection, (c) pressure gradient force, (d) gravity, and (e) acceleration associated with viscosity.

Typical Distributions of Water Characteristics in the Oceans

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

The effect of tides on the hydrophysical fields in the NEMO-shelf Arctic Ocean model. Maria Luneva National Oceanography Centre, Liverpool 2011 AOMIP meeting.

In the vicinity of mooring D, the bottom slope is α ≈ We show that for the stratification shown in Figure 1 (let N 0 =2f ) the frequency ω of bottom-trapped.

Exploring the mesoscale activity in the Solomon Sea: a complementary approach with a numerical model and altimetric data L. Gourdeau 1, J. Verron 2, A.

(Unit 6) Formulas and Definitions:. Association. A connection between data values.

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:

I. Objectives and Methodology DETERMINATION OF CIRCULATION IN NORTH ATLANTIC BY INVERSION OF ARGO FLOAT DATA Carole GRIT, Herlé Mercier The methodology.

Trevor J McDougall, Raf Ferrari & Ryan Holmes

TAIYO KOBAYASHI and Shinya Minato

TURBULENT MIXING IN THE MIXED LAYER/THERMOCLINE TRANSITION LAYER

Coordinated mixing experiments

Spatial Modes of Salinity and Temperature Comparison with PDO index

Global Statistics of Inertial Motions from Profiling Floats

Observations of the North Atlantic Subtropical Mode Water

Mark A. Bourassa and Qi Shi

TALLEY Copyright © 2011 Elsevier Inc. All rights reserved

Assessment of the Surface Mixed Layer Using Glider and Buoy Data

Impacts of Air-Sea Interaction on Tropical Cyclone Track and Intensity

Supervisor: Eric Chassignet

Presentation transcript:

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), upper bound and lower bound of transition layer (blue line and black line) were calculated and overlaid on the potential density field. The three seasonal cycles can be identified in this figure. In the first year, when the float passed through a region with high geostrophic EKE (refer to Figure 8), the results of calculation are noisy and it is hard to find TLTs. The seasonal thermocline largely counts for the TLTs change for this case. The EKE also decreased the peak value of N 2 (Figure 6). Abstract The transition layer between the surface mixed layer of the ocean and the stratified interior was examined using global Argo CTD profiles. The transition layer thicknesses (TLT) were calculated from the shape of the N 2 profile across the layer, and compared to mixed layer depths (MLD). A linear regression between TLT and MLD>150m gives a weak relationship with a slope of about The relatively low sampling resolution and Argo sampling scheme generate errors and bias for this calculation, which is investigated. Probability distribution functions are found and compared to other mixed layer statistics. In addition, the correlations between TLT and wind stress, and mesoscale eddy kinetic energy (EKE) are examined. References Johnston, T. M. S., and Rudnick, 2007: Observations of the Transition Layer. J. Phys. Ocean Lorbacher, K., et al., 2006: Ocean mixed layer depth: A subsurface proxy of ocean- atmosphere variability. J. Geophys. Res. Data and Method - Argo data The calculation uses Argo float data south of 30S, , and only the “good” Argo float data, which passed the quality control, were chosen. First, the N 2 profile were calculated, and then TLT were calculated by full width half maximum (FWHM) definition based on N 2 profile. - Quikscat data were used to calculate wind stress -AVISO absolute surface velocities were used to calculate geostrophic EKE Discussion - Different kinds of error exist in the TLT calculation, e.g. low resolution of Argo float profile or the FWHM method. More work is needed to improve the calculation method, or to find better statistics to quantify TLT. - We will investigate the relationship between TLT and other variables, to find the role of transition layer in water mass exchange between the mixed layer and the ocean interior. We also want to to find the effect of eddies in these process. Introduction The ocean mixed layer is commonly considered as a proxy of interaction between the atmosphere and the ocean interior with vertically uniform property. The transition layer is located at the base of mixed layer with elevated shear and stratification compare to the mixed layer above and interior below (Johnston and Rudnick, 2007). Transition layers can be defined by stratification, turbulence or its dynamics, and its thickness can be calculated from these definitions. Buoyancy, momentum and tracer fluxes applied at the ocean surface are transmitted to this layer from mixed layer into ocean interior. To understand the role of transition layer is important. In coarse resolution global climate models, adding a transition layer to link ocean surface mixing scheme to interior mixing scheme can improve the models. Ocean Transition Layer Thickness and Mixed Layer Depth Jun Dong, Kevin Speer GFDI, Department of Oceanography, Florida State University Relation between TLT and MLD After the biases were corrected, the relation between the medians of TLT and the means of MLD with one standard deviation, is shown in Figure 4. The figure shows that the calculation for MLD 200m part, because of the large sample number for the first part. The slope of linear regression for MLD 150m is 0.02 with intersection 7.3m. For the first part, we cannot trust this relation because of the large error. For the second part, the calculation gives weak relationship between them, which is smaller the value given by Johnston and Rudnick. The median for all TLTs is 14m. Good profile Transition layer Good profile (30S)53640 Transition layer (30S)23023 TLT Bias Simulation Large biases are caused by the coarse sampling resolution of Argo float. A simplified simulation was performed to quantify the biases. The procedure was to set N 2 peak vary from 90m to 110m with Gaussian shape, and TLT from 1m to 40m; Sample every 10m from surface (10m, 20m, …) as Argo float. The Figure 2 shows the biases, calculated TLT minus true TLT, and the expected TLT biases for each observed TLT are shown in Figure 3. The biases are always positive. The smaller the thickness, the larger the bias. In the wind stress and MLD plot (Figure 7), the MLD variation is related to the wind stress variation, and lags it. In the EKE and MLD plot (Figure 9), when the eddy is active in the first year, the deep MLD anomalies are collocated with large EKE. These mixed depth anomalies might be related to EKE or wind stress, but more investigation is needed. Figure 1. Schematic of transition layer definitions and transition layer thickness. (Johnston and Rudnick, 2007). Figure 2.Figure 3. Figure 5.Figure 4. Figure 7.Figure 6. Figure 9. Figure 8.