Your search keyword '"James B. Edson"' showing total 97 results

1. Saildrone Direct Covariance Wind Stress in Various Wind and Current Regimes of the Tropical Pacific

Author

J. E. Jack Reeves Eyre, Meghan F. Cronin, Dongxiao Zhang, Elizabeth J. Thompson, Christopher W. Fairall, and James B. Edson

Subjects

Atmospheric Science, Ocean Engineering

Abstract

High-frequency wind measurements from Saildrone autonomous surface vehicles are used to calculate wind stress in the tropical east Pacific. Comparison between direct covariance (DC) and bulk wind stress estimates demonstrates very good agreement. Building on previous work that showed the bulk input data were reliable, our results lend credibility to the DC estimates. Wind flow distortion by Saildrones is comparable to or smaller than other platforms. Motion correction results in realistic wind spectra, albeit with signatures of swell-coherent wind fluctuations that may be unrealistically strong. Fractional differences between DC and bulk wind stress magnitude are largest at wind speeds below 4 m s−1. The size of this effect, however, depends on choice of stress direction assumptions. Past work has shown the importance of using current-relative (instead of Earth-relative) winds to achieve accurate wind stress magnitude. We show that it is also important for wind stress direction. Significance Statement We use data from Saildrone uncrewed oceanographic research vehicles to investigate the horizontal forces applied to the surface of the ocean by the action of the wind. We compare two methods to calculate the forces: one uses several simplifying assumptions, and the other makes fewer assumptions but is error prone if the data are incorrectly processed. The two methods agree well, suggesting that Saildrone vehicles are suitable for both methods and that the data processing methods work. Our results show that it is important to consider ocean currents, as well as winds, in order to achieve accurate magnitude and direction of the surface forces.

Published

2023

2. Ocean Mesoscale and Frontal-Scale Ocean–Atmosphere Interactions and Influence on Large-Scale Climate: A Review

Author

Hyodae Seo, Larry W. O’Neill, Mark A. Bourassa, Arnaud Czaja, Kyla Drushka, James B. Edson, Baylor Fox-Kemper, Ivy Frenger, Sarah T. Gille, Benjamin P. Kirtman, Shoshiro Minobe, Angeline G. Pendergrass, Lionel Renault, Malcolm J. Roberts, Niklas Schneider, R. Justin Small, Ad Stoffelen, and Qing Wang

Subjects

Atmospheric Science

Abstract

Two decades of high-resolution satellite observations and climate modeling studies have indicated strong ocean–atmosphere coupled feedback mediated by ocean mesoscale processes, including semipermanent and meandrous SST fronts, mesoscale eddies, and filaments. The air–sea exchanges in latent heat, sensible heat, momentum, and carbon dioxide associated with this so-called mesoscale air–sea interaction are robust near the major western boundary currents, Southern Ocean fronts, and equatorial and coastal upwelling zones, but they are also ubiquitous over the global oceans wherever ocean mesoscale processes are active. Current theories, informed by rapidly advancing observational and modeling capabilities, have established the importance of mesoscale and frontal-scale air–sea interaction processes for understanding large-scale ocean circulation, biogeochemistry, and weather and climate variability. However, numerous challenges remain to accurately diagnose, observe, and simulate mesoscale air–sea interaction to quantify its impacts on large-scale processes. This article provides a comprehensive review of key aspects pertinent to mesoscale air–sea interaction, synthesizes current understanding with remaining gaps and uncertainties, and provides recommendations on theoretical, observational, and modeling strategies for future air–sea interaction research. Significance Statement Recent high-resolution satellite observations and climate models have shown a significant impact of coupled ocean–atmosphere interactions mediated by small-scale (mesoscale) ocean processes, including ocean eddies and fronts, on Earth’s climate. Ocean mesoscale-induced spatial temperature and current variability modulate the air–sea exchanges in heat, momentum, and mass (e.g., gases such as water vapor and carbon dioxide), altering coupled boundary layer processes. Studies suggest that skillful simulations and predictions of ocean circulation, biogeochemistry, and weather events and climate variability depend on accurate representation of the eddy-mediated air–sea interaction. However, numerous challenges remain in accurately diagnosing, observing, and simulating mesoscale air–sea interaction to quantify its large-scale impacts. This article synthesizes the latest understanding of mesoscale air–sea interaction, identifies remaining gaps and uncertainties, and provides recommendations on strategies for future ocean–weather–climate research.

Published

2023

3. Direct Observation of Wave-coherent Pressure Work in the Atmospheric Boundary Layer

Author

Seth F Zippel, James B Edson, Malcolm E. Scully, and Oaklin R Keefe

Abstract

Surface waves grow through a mechanism in which atmospheric pressure is offset in phase from the wavy surface. A pattern of low atmospheric pressure over upward wave orbital motions and high pressure over downward wave orbital motions travels with the water wave, leading to a pumping of kinetic energy from the atmospheric boundary layer into the waves. This pressure pattern persists above the air/water interface, modifying the turbulent kinetic energy in the atmospheric wave-affected boundary layer. Here, we present field measurements of the transfer of energy from wind to waves through wave-coherent atmospheric pressure work. Measured pressure work cospectra are consistent with an existing model for atmospheric pressure work. Measured pressure work energy fluxes reach 0.1-0.2 W m$^{-2}$ during the largest measured wind event (winds reaching 16.5 m s$^{-1}$). The implications for these measurements and their importance to the turbulent kinetic energy budget are discussed.

Published

2023

4. Air-Sea Trace Gas Fluxes: Direct and Indirect Measurements

Author

Christopher W. Fairall, Mingxi Yang, Sophia E. Brumer, Byron W. Blomquist, James B. Edson, Christopher J. Zappa, Ludovic Bariteau, Sergio Pezoa, Thomas G. Bell, and Eric S. Saltzman

Subjects

cardon dioxide (CO2), Global and Planetary Change, chemical enhancement, direct observation, bubble mediated transfer, bulk algorithm, Ocean Engineering, Aquatic Science, Oceanography, Water Science and Technology, gas transfer velocity, COARE gas flux parameterization, Dimethylsufide (DMS)

Abstract

The past decade has seen significant technological advance in the observation of trace gas fluxes over the open ocean, most notably CO2, but also an impressive list of other gases. Here we will emphasize flux observations from the air-side of the interface including both turbulent covariance (direct) and surface-layer similarity-based (indirect) bulk transfer velocity methods. Most applications of direct covariance observations have been from ships but recently work has intensified on buoy-based implementation. The principal use of direct methods is to quantify empirical coefficients in bulk estimates of the gas transfer velocity. Advances in direct measurements and some recent field programs that capture a considerable range of conditions with wind speeds exceeding 20 ms-1 are discussed. We use coincident direct flux measurements of CO2 and dimethylsulfide (DMS) to infer the scaling of interfacial viscous and bubble-mediated (whitecap driven) gas transfer mechanisms. This analysis suggests modest chemical enhancement of CO2 flux at low wind speed. We include some updates to the theoretical structure of bulk parameterizations (including chemical enhancement) as framed in the COAREG gas transfer algorithm.

Published

2022

5. On Assessing ERA5 and MERRA2 Representations of Cold-Air Outbreaks Across the Gulf Stream

Author

Armin Sorooshian, Florian Tornow, Taylor Shingler, Xubin Zeng, Luke D. Ziemba, C. Seethala, Hailong Wang, Xiang-Yu Li, David Painemal, Paquita Zuidema, Lee Thornhill, Gao Chen, James B. Edson, Michael A. Brunke, C. E. Robinson, and Michael Shook

Subjects

Gulf Stream, Boundary layer, Geophysics, Cold front, Flux (metallurgy), Buoy, General Earth and Planetary Sciences, Environmental science, Humidity, Westerlies, Dropsonde, Atmospheric sciences, Article

Abstract

The warm Gulf Stream sea surface temperatures strongly impact the evolution of winter clouds behind atmospheric cold fronts. Such cloud evolution remains challenging to model. The Gulf Stream is too wide within the ERA5 and MERRA2 reanalyses, affecting the turbulent surface fluxes. Known problems within the ERA5 boundary layer (too-dry and too-cool with too strong westerlies), ascertained primarily from ACTIVATE 2020 campaign aircraft dropsondes and secondarily from older buoy measurements, reinforce surface flux biases. In contrast, MERRA2 winter surface winds and air-sea temperature/humidity differences are slightly too weak, producing surface fluxes that are too low. Reanalyses boundary layer heights in the strongly forced winter cold-air-outbreak regime are realistic, whereas late-summer quiescent stable boundary layers are too shallow. Nevertheless, the reanalysis biases are small, and reanalyses adequately support their use for initializing higher-resolution cloud process modeling studies of cold-air outbreaks.

Published

2021

6. Towards a Characterization of the Ka-Band Ocean Surface Backscattering Mechanisms

Author

Federica Polverari, J. Max Adam, J. Thomas Farra, James B. Edson, Ernesto Rodriguez, Alexander Wineteer, Paul Siqueira, and Dragana Perkovic-Martin

Subjects

Surface (mathematics), Backscatter, Atmospheric model, Scatterometer, Physics::Geophysics, Characterization (materials science), Ocean dynamics, symbols.namesake, symbols, Ka band, Doppler effect, Physics::Atmospheric and Oceanic Physics, Geology, Remote sensing

Abstract

The Ka-band wind scatterometry is a relatively new methodology to retrieve ocean surface winds. Modeling the Ka-band ocean surface backscatter is challenging, especially because of the lack of in-situ measurements. In the framework of the NASA Earth Ventures Suborbital-3 Submesoscale Ocean Dynamics Experiment (S-MODE) mission, a new data set of ocean surface backscatter has been collected. These measurements were obtained from a Ka-band Doppler scatterometer (KaBODS) located on the Woods Hole Oceanographic Institution (WHOI) Air-Sea Interaction Tower (ASIT). In this work we present our analysis and findings on the KaBODS backscatter measurements based on the development of a wind empirical backscatter model. We show that the data are characterized by a large variability, which is mainly due to intrinsic geophysical effects. The source of this geophysical variability is currently under investigation.

Published

2021

7. Diurnal Surface Flux Variability Over Western Boundary Currents

Author

Carol Anne Clayson and James B. Edson

Subjects

Surface (mathematics), Geophysics, Planetary boundary layer, General Earth and Planetary Sciences, Environmental science, Flux, Atmospheric sciences, Boundary current

Published

2019

8. Parameterizing Air‐Water Gas Exchange in the Shallow, Microtidal New River Estuary

Author

James B. Edson, Craig R. Tobias, and Bryce Van Dam

Subjects

Convection, Hydrology, Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Eddy covariance, Paleontology, Soil Science, Forestry, Estuary, Aquatic Science, Environmental science, Air water, Water Science and Technology

Abstract

Estuarine CO2 emissions are important components of regional and global carbon budgets, but assessments of this flux are plagued by uncertainties associated with gas transfer velocity (k) parameterization. We combined direct eddy covariance measurements of CO2 flux with water‐side pCO2 determinations to generate more reliable k parameterizations for use in small estuaries. When all data were aggregated, k was described well by a linear relationship with wind speed (U10), in a manner consistent with prior open‐ocean and estuarine k parameterizations. However, k was significantly greater at night and under low wind speed, and nighttime k was best predicted by a parabolic, rather than linear, relationship with U10. We explored the effect of water‐side thermal convection, but found only a weak correlation between convective scale and k. Hence, while convective forcing may be important at times, it appears that factors besides water‐side thermal convection were likely responsible for the bulk of the observed nighttime enhancement in k. Regardless of source, we show that these day‐night differences in k should be accounted for when CO2 emissions are assessed over short time scales, or when pCO2 is constant and U10 varies. On the other hand, when temporal variability in pCO2 is large, it exerts greater control over CO2 fluxes than does k parameterization. In these cases, the use of a single k value, or a simple linear relationship with U10 is often sufficient. This study provides important guidance for k parameterization in shallow, or microtidal estuaries, especially when diel processes are considered.

Published

2019

9. SPURS-2: Salinity Processes in the Upper-Ocean Regional Study 2 – The Eastern Equatorial Pacific Experiment

Author

James B. Edson, Nasa, Julian Schanze, Andrey Y. Shcherbina, and Eric Lindstrom

Subjects

Salinity, lcsh:Oceanography, freshwater cycle, Oceanography, Environmental science, SPURS-2, ocean salinity, lcsh:GC1-1581

Abstract

In this special issue of Oceanography we explore the results of SPURS-2, the second Salinity Processes in the Upper-ocean Regional Study (SPURS), conducted in the eastern equatorial Pacific. SPURS is an ambitious multiyear field program to study surface salinity in evaporation-​dominated (SPURS-1) and precipitation-dominated (SPURS-2) regions of the global ocean. The primary goal was to further our understanding of the global oceanic freshwater cycle through investigation of the physical processes controlling the upper-ocean salinity balance: air-sea interactions, transport, and mixing. With the advent of satellites capable of measuring sea surface salinity, such as NASA’s Aquarius instrument and the Soil Moisture Active Passive (SMAP) satellite, as well as the European Space Agency’s Soil Moisture and Ocean Salinity (SMOS) platform, a near-synoptic view of such processes has become possible (Figure 1). To take full advantage of such observations, we need to understand the link between upper-ocean dynamics and the oceanic freshwater cycle.

Published

2019

10. Novel and Flexible Approach to Access the Open Ocean: Uses of Sailing Research Vessel Lady Amber During SPURS-2

Author

Kyla Drushka, Julian Schanze, Luca Centurioni, J. Thomas Farrar, Luc Rainville, William E. Asher, Carol Anne Clayson, Andrey Y. Shcherbina, Benjamin A. Hodges, James B. Edson, and Verena Hormann

Subjects

Oceanography, Geology, Research vessel, Marine engineering

Published

2019

11. Effects of Rainfall on the Atmosphere and the Ocean During SPURS-2

Author

James B. Edson, Carol Anne Clayson, Aaron Paget, Raymond Graham, and Benjamin Greenwood

Subjects

Atmosphere, Environmental science, Oceanography, Atmospheric sciences

Published

2019

12. Effects of Sea State and Small-Scale Currents on Air-Sea Fluxes in the Northwest Tropical Atlantic Ocean

Author

Hyodae Seo, César Sauvage, Carol Anne Clayson, and James B. Edson

Subjects

Oceanography, Scale (ratio), Environmental science, Sea state, Tropical Atlantic, Physics::Atmospheric and Oceanic Physics

Abstract

The Northwest Tropical Atlantic is characterized by the strong North Brazilian Current (NBC), its rings, and numerous mesoscale eddies, which ceaselessly interact with the persistent trade winds and trade cumuli. Near the coast, the ocean stratification is maintained by the Amazon and Orinoco river discharges, which control the vertical mixing and the near-shore circulation dynamics. Breaking waves and swells are ubiquitous under the trade winds, and hence, the wave-induced mixing and wave-mediated air-sea fluxes are expected to modulate the eddy variability and low-level clouds. Our study aims to enhance understanding of the air-sea fluxes mediated by the mesoscale ocean currents and surface waves and evaluate their impacts on the ocean and atmosphere.High-resolution ocean model (ROMS) and wave model (WW3) simulations are conducted for the period of the ATOMIC/EUREC4A experiments. The model surface state variables are used to compute offline the air-sea heat and momentum fluxes using the latest COARE v3.6 bulk flux algorithm under various sea state conditions induced by surface waves, ocean currents, and their interaction. The results demonstrate that considering the spatial variability in sea states via wave slope and wave age (e.g., swells and wind-seas) leads to enhanced spatial variability in drag coefficient and wind stress. Comparison to wind stress estimated using the wind-speed dependent formulation, meaning that COARE makes sea state assumptions under given wind, indicates that, at any given time, wind and wave in fact, rarely match those assumptions. The swells (wind-seas) decreases (increases) the sea surface roughness length, drag coefficient, and wind stress by 10-15%. However, we find that the sea state impact on turbulent heat flux is negligible.More importantly, we also show that considering the ocean currents in the COARE algorithm yields much stronger spatio-temporal variations in not just the wind stress but also turbulent heat fluxes. The intense and small-scale current fields in this region are associated with the NBC and its rings, smaller mesoscale eddies, and filamentary density fronts associated with the freshwater plumes. The surface currents associated with these small-scale energetic features alter the relative wind speed and thus the air-sea fluxes depending on the directional alignment between the wind and current; the increase (decrease) in both the wind and heat fluxes by ~20% is found with the current and wind are in the opposite (same) direction wind. Moreover, this relative wind effect appears to be reinforced by wave direction as well, also via the directional alignment between waves and currents, since the waves are mainly aligned with the trade wind in this region.Further analyses are underway to examining the seasonality of the modulation by the wave-current interaction, quantifying the role of the freshwater distribution, and exploring the time-mean influence on the low-level clouds. The results from the ocean and wave modeling efforts will guide our ongoing fully coupled ocean-atmosphere (and wave) model simulations to quantify their impacts on the atmosphere, including low-level clouds.

Published

2021

13. Super Sites for Advancing Understanding of the Oceanic and Atmospheric Boundary Layers

Author

Sebastiaan Swart, Christopher J. Zappa, Sarah T. Gille, Dongxiao Zhang, Meghan F. Cronin, Ana Beatriz Villas Bôas, Frank E. Muller-Karger, James B. Edson, Luca Centurioni, Rhys Parfitt, Carol Anne Clayson, Laura D Riihimaki, Douglas Vandemark, and Shawn R. Smith

Subjects

Meteorology, Planetary boundary layer, Boundary (topology), Forecast skill, Ocean Engineering, Weather and climate, Oceanography, Marine Biology & Hydrobiology, Climate Action, Earth system science, Temporal resolution, Greenhouse gas, Life Below Water, Maritime Engineering, Physics::Atmospheric and Oceanic Physics, Mixing (physics), Geology

Abstract

Author(s): Clayson, Carol Anne; Centurioni, Luca; Cronin, Meghan F; Edson, James; Gille, Sarah; Muller-Karger, Frank; Parfitt, Rhys; Riihimaki, Laura D; Smith, Shawn R; Swart, Sebastiaan; Vandemark, Douglas; Boas, Ana Beatriz Villas; Zappa, Christopher J; Zhang, Dongxiao | Abstract: Abstract Air‐sea interactions are critical to large-scale weather and climate predictions because of the ocean's ability to absorb excess atmospheric heat and carbon and regulate exchanges of momentum, water vapor, and other greenhouse gases. These exchanges are controlled by molecular, turbulent, and wave-driven processes in the atmospheric and oceanic boundary layers. Improved understanding and representation of these processes in models are key for increasing Earth system prediction skill, particularly for subseasonal to decadal time scales. Our understanding and ability to model these processes within this coupled system is presently inadequate due in large part to a lack of data: contemporaneous long-term observations from the top of the marine atmospheric boundary layer (MABL) to the base of the oceanic mixing layer.We propose the concept of “Super Sites” to provide multi-year suites of measurements at specific locations to simultaneously characterize physical and biogeochemical processes within the coupled boundary layers at high spatial and temporal resolution. Measurements will be made from floating platforms, buoys, towers, and autonomous vehicles, utilizing both in-situ and remote sensors. The engineering challenges and level of coordination, integration, and interoperability required to develop these coupled ocean‐atmosphere Super Sites place them in an “Ocean Shot” class.

Published

2021

14. Air–Sea Interaction in the Southern Ocean: Exploring the Height of the Wave Boundary Layer at the Air–Sea Interface

Author

Alejandro Cifuentes-Lorenzen, Christopher J. Zappa, and James B. Edson

Subjects

Physics, Atmospheric Science, Momentum (technical analysis), 010504 meteorology & atmospheric sciences, 010505 oceanography, Flux, Energy flux, 01 natural sciences, Computational physics, Boundary layer, Wavenumber, 14. Life underwater, Phase velocity, Exponential decay, 0105 earth and related environmental sciences, Dimensionless quantity

Abstract

We investigate the momentum and energy exchange across the wave boundary layer (WBL). Directly at the air–sea interface, we test three wave-growth parametrizations by comparing estimates of the wave-induced momentum flux derived from wave spectra with direct covariance estimates of the momentum flux. An exponential decay is used to describe the vertical structure of the wave-induced momentum in the atmospheric WBL through use of a decay rate, a function of the dimensionless decay rate and wavenumber (A = α k). The decay rate is varied to minimize the difference between the energy extracted from the WBL and the energy flux computed from wave spectra using our preferred wave-growth parametrization. For wave ages (i.e. the peak phase speed to atmospheric friction velocity ratio) in the range $$ 15 < c_{p}/u_{*} < 35 $$ we are able to balance these two estimates to within 10%. The decay rate is used to approximate the WBL height as the height to which the wave-induced flux is 0.1 of its surface value and the WBL height determined this way is found to be between 1–3 m. Finally, we define an effective phase speed with which to parametrize the energy flux for comparison with earlier work, which we ultimately attempt to parametrize as a function of wind forcing.

Published

2018

15. On Estimating the Surface Wind Stress over the Sea

Author

James B. Edson, Tihomir Hristov, Larry Mahrt, and Scott D. Miller

Subjects

Surface (mathematics), Marine boundary layer, 010504 meteorology & atmospheric sciences, Field (physics), 010505 oceanography, Wind stress, Oceanography, 01 natural sciences, Tower, Geology, 0105 earth and related environmental sciences, Marine engineering

Abstract

Our study analyzes measurements primarily from two Floating Instrument Platform (FLIP) field programs and from the Air–Sea Interaction Tower (ASIT) site to examine the relationship between the wind and sea surface stress for contrasting conditions. The direct relationship of the surface momentum flux to U2 is found to be better posed than the relationship between and U, where U is the wind speed and is the friction velocity. Our datasets indicate that the stress magnitude often decreases significantly with height near the surface due to thin marine boundary layers and/or enhanced stress divergence close to the sea surface. Our study attempts to correct the surface stress estimated from traditional observational levels by using multiple observational levels near the surface and extrapolating to the surface. The effect of stability on the surface stress appears to be generally smaller than errors due to the stress divergence. Definite conclusions require more extensive measurements close to the sea surface.

Published

2018

16. Sensitivity of Offshore Surface Fluxes and Sea Breezes to the Spatial Distribution of Sea-Surface Temperature

Author

Kelly Lombardo, Eric Sinsky, Michael M. Whitney, James B. Edson, and Yan Jia

Subjects

Atmospheric Science, Buoyancy, 010504 meteorology & atmospheric sciences, Meteorology, 010505 oceanography, Planetary boundary layer, engineering.material, Atmospheric sciences, Spatial distribution, 01 natural sciences, Stability (probability), Sea surface temperature, Sea breeze, Marine layer, engineering, Environmental science, Submarine pipeline, 0105 earth and related environmental sciences

Abstract

A series of numerical sensitivity experiments is performed to quantify the impact of sea-surface temperature (SST) distribution on offshore surface fluxes and simulated sea-breeze dynamics. The SST simulations of two mid-latitude sea-breeze events over coastal New England are performed using a spatially-uniform SST, as well as spatially-varying SST datasets of 32- and 1-km horizontal resolutions. Offshore surface heat and buoyancy fluxes vary in response to the SST distribution. Local sea-breeze circulations are relatively insensitive, with minimal differences in vertical structure and propagation speed among the experiments. The largest thermal perturbations are confined to the lowest 10% of the sea-breeze column due to the relatively high stability of the mid-Atlantic marine atmospheric boundary layer (ABL) suppressing vertical mixing, resulting in the depth of the marine layer remaining unchanged. Minimal impacts on the column-averaged virtual potential temperature and sea-breeze depth translates to small changes in sea-breeze propagation speed. This indicates that the use of datasets with a fine-scale SST may not produce more accurate sea-breeze simulations in highly stable marine ABL regimes, though may prove more beneficial in less stable sub-tropical environments.

Published

2017

17. Wave‐Related Reynolds Number Parameterizations of CO 2 and DMS Transfer Velocities

Author

Alejandro Cifuentes-Lorenzen, Christopher J. Zappa, Barry J. Huebert, Byron Blomquist, Sophia E. Brumer, Christopher W. Fairall, James B. Edson, and Ian M. Brooks

Subjects

Physics, 010504 meteorology & atmospheric sciences, 010505 oceanography, Reynolds number, Breaking wave, Sea state, Mechanics, Atmospheric sciences, 01 natural sciences, Wind speed, Wind wave model, Wave model, symbols.namesake, Geophysics, Mass transfer, Wind wave, symbols, General Earth and Planetary Sciences, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences

Abstract

Predicting future climate hinges on our understanding of and ability to quantify air‐sea gas transfer. The latter relies on parameterizations of the gas transfer velocity k, which represents physical mass transfer mechanisms and is usually parameterized as a nonlinear function of wind forcing. In an attempt to reduce uncertainties in k, this study explores empirical parameterizations that incorporate both wind speed and sea state dependence via wave‐wind and breaking Reynolds numbers, RH and RB. Analysis of concurrent eddy covariance gas transfer and measured wavefield statistics supplemented by wave model hindcasts shows for the first time that wave‐related Reynolds numbers collapse four open ocean data sets that have a wind speed dependence of CO₂ transfer velocity ranging from lower than quadratic to cubic. Wave‐related Reynolds number and wind speed show comparable performance for parametrizing dimethyl sulfide (DMS) which, because of its higher solubility, is less affected by bubble‐mediated exchange associated with wave breaking.

Published

2017

18. Sensors for Micrometeorological and Flux Measurements

Author

James B. Edson and Neil J. Williams

Published

2019

19. Comparison of Direct Covariance Flux Measurements from an Offshore Tower and a Buoy

Author

Joachim Reuder, Martin Flügge, Mostafa Bakhoday Paskyabi, Albert J. Plueddemann, and James B. Edson

Subjects

Atmospheric Science, Physical Meteorology and Climatology, 010504 meteorology & atmospheric sciences, Computation, Flux, Ocean Engineering, Buoy observations, 01 natural sciences, Quality assurance/control, Observatory, Circulation/ Dynamics, Observational techniques and algorithms, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, Remote sensing, Atm/Ocean Structure/ Phenomena, Air-sea interaction, Buoy, 010505 oceanography, Turbulence, Covariance, Boundary layer, Environmental science, Submarine pipeline, Tower

Abstract

Direct covariance flux (DCF) measurements taken from floating platforms are contaminated by wave-induced platform motions that need to be removed before computation of the turbulent fluxes. Several correction algorithms have been developed and successfully applied in earlier studies from research vessels and, most recently, by the use of moored buoys. The validation of those correction algorithms has so far been limited to short-duration comparisons against other floating platforms. Although these comparisons show in general a good agreement, there is still a lack of a rigorous validation of the method, required to understand the strengths and weaknesses of the existing motion-correction algorithms. This paper attempts to provide such a validation by a comparison of flux estimates from two DCF systems, one mounted on a moored buoy and one on the Air–Sea Interaction Tower (ASIT) at the Martha’s Vineyard Coastal Observatory, Massachusetts. The ASIT was specifically designed to minimize flow distortion over a wide range of wind directions from the open ocean for flux measurements. The flow measurements from the buoy system are corrected for wave-induced platform motions before computation of the turbulent heat and momentum fluxes. Flux estimates and cospectra of the corrected buoy data are found to be in very good agreement with those obtained from the ASIT. The comparison is also used to optimize the filter constants used in the motion-correction algorithm. The quantitative agreement between the buoy data and the ASIT demonstrates that the DCF method is applicable for turbulence measurements from small moving platforms, such as buoys.

Published

2016

20. Sensitivity of Simulated Sea Breezes to Initial Conditions in Complex Coastal Regions

Author

Michael M. Whitney, Yan Jia, James B. Edson, Kelly Lombardo, and Eric Sinsky

Subjects

Horizontal resolution, Atmospheric Science, 010504 meteorology & atmospheric sciences, Land surface temperature, Diurnal temperature variation, Mesoscale meteorology, Humidity, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Sea breeze, Climatology, Environmental science, Sensitivity (control systems), 0105 earth and related environmental sciences, Coastal sea

Abstract

Mesoscale simulations of sea breezes are sensitive to the analysis product used to initialize the simulations, primarily due to the representation of the coastline and the coastal sea surface temperatures (SSTs) in the analyses. The use of spatially coarse initial conditions, relative to the horizontal resolution of the mesoscale model grid, can introduce errors in the representation of coastal SSTs, in part due to the incorrect designation of the land surface. As a result, portions of the coastal ocean are initialized with land surface temperature values and vice versa. The diurnal variation of the sea surface is typically smaller than over land on meso- and synoptic-scale time scales. Therefore, it is common practice to retain a temporally static SST in numerical simulations, causing initial SST errors to persist through the duration of the simulation. These SST errors influence horizontal coastal temperature and humidity gradients and thereby the development of the sea-breeze circulations. The authors developed a technique to modify the initial surface conditions created from a reanalysis product [North American Regional Reanalysis (NARR)] for simulations of two sea-breeze events over the New England coast to more accurately represent the finescale structure of the coastline and the spatial representation of the coastal land surface and SST. Using this technique, the coastal SST (2-m temperature) RMSE is reduced from as much as 25°–1°C (7°–1°C), contributing to a more accurate propagation of the sea-breeze front. Techniques described in this work may be important for mesoscale simulations and forecasts of other coastal phenomena.

Published

2016

21. In Situ and Satellite Evaluation of Air–Sea Flux Variation near Ocean Temperature Gradients

Author

Douglas Vandemark, Amanda M. Plagge, and James B. Edson

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Buoy, Mesoscale meteorology, Wind stress, Stratification (water), Scatterometer, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Sea surface temperature, Heat flux, Climatology, Atmospheric instability, Environmental science, 0105 earth and related environmental sciences

Abstract

Observations of ocean–atmosphere coupling across persistent mesoscale sea surface temperature (SST) gradients are used to examine the controls of atmospheric stability, pressure gradient force, and heat flux that are considered central to oft-observed coupling between wind and SST. Moored air–sea flux measurements near the Gulf Stream are combined with QuikSCAT satellite scatterometer equivalent neutral wind (ENW) data to assess correlations between SST, air–sea fluxes, pressure, and wind perturbations at scales of 10–100 days. The net effect of ocean fronts meandering past the site enabled buoy observation of SST impacts on wind, with coupling coefficients of 0.3–0.5 similar to past studies. Wind stress–SST and ENW–SST correlation coefficients are slightly higher, and roughly 20% of the ENW perturbation is attributed to stratification impacts predicted by Monin–Obukhov (MO) similarity theory. Significantly higher correlation is observed when relating wind or stress perturbations to buoyant heat flux variation. Atmospheric pressure perturbation with SST of order 0.5 hPa °C−1 is observed, as well as high negative correlation between wind and pressure variations. Length and time scales associated with the coupling indicate that peak correlations occur at 50–70 days and 300–500 km, consistent with mesoscale meander scales. Coupling coefficient values vary significantly depending on analysis time scale and exhibit a range near to recently observed interbasin variability. This variability is attributed to the extent of oceanic length scales permitted in the analysis. Together, results affirm the central role of SST-induced turbulent heat flux in controlling pressure field adjustments and thereby the wind perturbations over SST fronts.

Published

2016

22. Coastal Zone Surface Stress with Stable Stratification

Author

Edgar L. Andreas, Jielun Sun, Dean Vickers, Larry Mahrt, James B. Edson, and Edward G. Patton

Subjects

010504 meteorology & atmospheric sciences, 010505 oceanography, Mixed layer, Advection, Stratification (water), Wind direction, Oceanography, Atmospheric sciences, 01 natural sciences, Wind speed, Swell, Warm front, Climatology, Environmental science, Shear velocity, 0105 earth and related environmental sciences

Abstract

Summertime eddy correlation measurements from an offshore tower are analyzed to investigate the dependence of the friction velocity for stable conditions on the mean wind speed V, air–sea difference of virtual potential temperature δθυ, and nonstationary submeso motions. The quantity δθυ sometimes exceeds 3°C, usually because of the advection of warm air from land over cooler water at this site. Thin stable boundary layers result. Unexpectedly, does not depend systematically on the stratification δθυ even for weak winds. For weak winds, increases systematically with increasing submeso variations of the wind. The relationship for a given V is greater in nonstationary conditions. Additionally, this study examines as a function of wind direction. The relationship appears to be affected by swell direction for weak winds and advection from land for short fetches.

Published

2016

23. Characterizing marine atmospheric boundary layer to support offshore wind energy research

Author

James B. Edson and Houshuo Jiang

Subjects

History, Offshore wind power, Planetary boundary layer, Environmental science, Atmospheric sciences, Computer Science Applications, Education

Abstract

The marine atmospheric boundary layer (MABL), under most wind conditions, is characterized by lower shear, less turbulence, and higher winds than its terrestrial counterpart, thereby making offshore wind farms attractive enough to offset higher costs of construction and maintenance. Significant questions, however, remain about the structure and characteristics of the MABL and its impact on wind turbines. This work characterizes the structure of the MABL in the coastal region south of Martha’s Vineyard where offshore wind turbines are planned to operate, using in situ and remotely sensed LIDAR measurements and numerical data generated by high resolution Weather Research and Forecasting (WRF) modeling. This work will benefit wind power estimates and short-term energy forecasting.

Published

2020

24. A Study of CINDY/DYNAMO MJO Suppressed Phase

Author

Paul May, Toshiaki Shinoda, Ming Liu, Christopher W. Fairall, Tommy G. Jensen, James B. Edson, James Cummings, Sue Chen, Maria Flatau, Dariusz B. Baranowski, Paul E. Ciesielski, Nan-Hsun Chi, Jerome M. Schmidt, Simon P. de Szoeke, and Ren-Chieh Lien

Subjects

Atmosphere, Atmospheric Science, Sea surface temperature, Precipitable water, Climatology, Mesoscale meteorology, Phase (waves), Environmental science, Hindcast, Madden–Julian oscillation, Atmospheric sciences, Dynamo

Abstract

The diurnal variability and the environmental conditions that support the moisture resurgence of MJO events observed during the Cooperative Indian Ocean Experiment on Intraseasonal Variability (CINDY)/DYNAMO campaign in October–December 2011 are investigated using in situ observations and the cloud-resolving fully air–ocean–wave Coupled Ocean–Atmosphere Mesoscale Prediction System (COAMPS). Spectral density and wavelet analysis of the total precipitable water (TPW) constructed from the DYNAMO soundings and TRMM satellite precipitation reveal a deep layer of vapor resurgence during the observed Wheeler and Hendon real-time multivariate MJO index phases 5–8 (MJO suppressed phase), which include diurnal, quasi-2-, quasi-3–4-, quasi-6–8-, and quasi-16-day oscillations. A similar oscillatory pattern is found in the DYNAMO moorings sea surface temperature analysis, suggesting a tightly coupled atmosphere and ocean system during these periods. COAMPS hindcast focused on the 12–16 November 2011 event suggests that both the diurnal sea surface temperature (SST) pumping and horizontal and vertical moisture transport associated with the westward propagating mixed Rossby–Gravity (MRG) waves play an essential role in the moisture resurgence during this period. Idealized COAMPS simulations of MRG waves are used to estimate the MRG and diurnal SST contributions to the overall moisture increase. These idealized MRG sensitivity experiments showed the TPW increase varies from 9% to 13% with the largest changes occurring in the simulations that included a diurnal SST variation of 2.5°C as observed.

Published

2015

25. Salinity and Temperature Balances at the SPURS Central Mooring During Fall and Winter

Author

James B. Edson, Benjamin A. Hodges, Stephen C. Riser, Craig M. Lee, Charles C. Eriksen, Luc Rainville, William S. Kessler, Albert J. Plueddemann, Raymond W. Schmitt, David M. Fratantoni, and J. Thomas Farrar

Subjects

Salinity, lcsh:Oceanography, Oceanography, air-sea fluxes, Climatology, SPURS, upper-ocean salinity, Environmental science, lcsh:GC1-1581, sea surface salinity, Mooring, ocean temperature

Abstract

One part of the Salinity Processes in the Upper-ocean Regional Study (SPURS) field campaign focused on understanding the physical processes affecting the evolution of upper-ocean salinity in the region of climatological maximum sea surface salinity in the subtropical North Atlantic (SPURS-1). An upper-ocean salinity budget provides a useful framework for increasing this understanding. The SPURS-1 program included a central heavily instrumented mooring for making accurate measurements of air-sea surface fluxes, as well as other moorings, Argo floats, and gliders that together formed a dense observational array. Data from this array are used to estimate terms in the upper-ocean salinity and heat budgets during the SPURS-1 campaign, with a focus on the first several months (October 2012 to February 2013) when the surface mixed layer was becoming deeper, fresher, and cooler. Specifically, we examine the salinity and temperature balances for an upper-ocean mixed layer, defined as the layer where the density is within 0.4 kg m–3 of its surface value. The gross features of the evolution of upper-ocean salinity and temperature during this fall/winter season are explained by a combination of evaporation and precipitation at the sea surface, horizontal transport of heat and salt by mixed-layer currents, and vertical entrainment of fresher, cooler fluid into the layer as it deepened. While all of these processes were important in the observed seasonal (fall) freshening at this location in the salinity-maximum region, the variability of salinity on monthly-to-intraseasonal time scales resulted primarily from horizontal advection.

Published

2015

26. The MJO and Air–Sea Interaction in TOGA COARE and DYNAMO

Author

Ludovic Bariteau, Christopher W. Fairall, J. R. Marion, James B. Edson, and Simon P. de Szoeke

Subjects

Convection, Atmospheric Science, Ocean current, Wind stress, Madden–Julian oscillation, Atmospheric sciences, Physics::Geophysics, Atmosphere, Sea surface temperature, Heat flux, Climatology, Astrophysics::Solar and Stellar Astrophysics, Environmental science, Outgoing longwave radiation, Physics::Atmospheric and Oceanic Physics

Abstract

Dynamics of the Madden–Julian Oscillation (DYNAMO) and Tropical Ocean and Global Atmosphere Coupled Ocean–Atmosphere Response Experiment (TOGA COARE) observations and reanalysis-based surface flux products are used to test theories of atmosphere–ocean interaction that explain the Madden–Julian oscillation (MJO). Negative intraseasonal outgoing longwave radiation, indicating deep convective clouds, is in phase with increased surface wind stress, decreased solar heating, and increased surface turbulent heat flux—mostly evaporation—from the ocean to the atmosphere. Net heat flux cools the upper ocean in the convective phase. Sea surface temperature (SST) warms during the suppressed phase, reaching a maximum before the onset of MJO convection. The timing of convection, surface flux, and SST is consistent from the central Indian Ocean (70°E) to the western Pacific Ocean (160°E). Mean surface evaporation observed in TOGA COARE and DYNAMO (110 W m−2) accounts for about half of the moisture supply for the mean precipitation (210 W m−2 for DYNAMO). Precipitation maxima are an order of magnitude larger than evaporation anomalies, requiring moisture convergence in the mean, and on intraseasonal and daily time scales. Column-integrated moisture increases 2 cm before the convectively active phase over the Research Vessel (R/V) Roger Revelle in DYNAMO, in accordance with MJO moisture recharge theory. Local surface evaporation does not significantly recharge the column water budget before convection. As suggested in moisture mode theories, evaporation increases the moist static energy of the column during convection. Rather than simply discharging moisture from the column, the strongest daily precipitation anomalies in the convectively active phase accompany the increasing column moisture.

Published

2015

27. Air–Sea Interactions from Westerly Wind Bursts During the November 2011 MJO in the Indian Ocean

Author

Steven A. Rutledge, Christopher W. Fairall, Elizabeth J. Thompson, H. Langley DeWitt, James B. Edson, Richard H. Johnson, William D. Smyth, Christopher J. Zappa, Simon P. de Szoeke, Aurélie J. Moulin, and James N. Moum

Subjects

Madden-Julian oscillation, Convection, Atmospheric Science, Equator, Madden–Julian oscillation, Westerlies, Physical oceanography, Oceanography, Atmospheric sciences, Atmosphere, symbols.namesake, Meteorology, Ocean-atmosphere interaction--Research, Climatology, symbols, Hydrology, Tropical cyclone, Kelvin wave, Geology

Abstract

The life cycles of three Madden–Julian oscillation (MJO) events were observed over the Indian Ocean as part of the Dynamics of the MJO (DYNAMO) experiment. During November 2011 near 0°, 80°E, the site of the research vessel Roger Revelle, the authors observed intense multiscale interactions within an MJO convective envelope, including exchanges between synoptic, meso, convective, and turbulence scales in both atmosphere and ocean and complicated by a developing tropical cyclone. Embedded within the MJO event, two bursts of sustained westerly wind (>10 m s−1; 0–8-km height) and enhanced precipitation passed over the ship, each propagating eastward as convectively coupled Kelvin waves at an average speed of 8.6 m s−1. The ocean response was rapid, energetic, and complex. The Yoshida–Wyrtki jet at the equator accelerated from less than 0.5 m s−1 to more than 1.5 m s−1 in 2 days. This doubled the eastward transport along the ocean's equatorial waveguide. Oceanic (subsurface) turbulent heat fluxes were comparable to atmospheric surface fluxes, thus playing a comparable role in cooling the sea surface. The sustained eastward surface jet continued to energize shear-driven entrainment at its base (near 100-m depth) after the MJO wind bursts subsided, thereby further modifying sea surface temperature for a period of several weeks after the storms had passed.

Published

2014

28. A Multisensor Comparison of Ocean Wave Frequency Spectra from a Research Vessel during the Southern Ocean Gas Exchange Experiment

Author

Alejandro Cifuentes-Lorenzen, Christopher J. Zappa, James B. Edson, and Ludovic Bariteau

Subjects

Atmospheric Science, Electromagnetic spectrum, Doppler radar, Ocean Engineering, Oceanography, Noise floor, law.invention, symbols.namesake, law, Wind wave, Ocean waves--Spectra, symbols, Altimeter, Hydrology, Ocean waves--Measurement, Radar, Significant wave height, Doppler effect, Geology, Remote sensing

Abstract

Obtaining accurate measurements of wave statistics from research vessels remains a challenge due to the platform motion. One principal correction is the removal of ship heave and Doppler effects from point measurements. Here, open-ocean wave measurements were collected using a laser altimeter, a Doppler radar microwave sensor, a radar-based system, and inertial measurement units. Multiple instruments were deployed to capture the low- and high-frequency sea surface displacements. Doppler and motion correction algorithms were applied to obtain a full 1D (0.035–1.3 ± 0.2 Hz) wave spectrum. The radar-based system combined with the laser altimeter provided the optimal low- and high-frequency combination, producing a frequency spectrum in the range from 0.035 to 1.2 Hz for cruising speeds ≤3 m s−1 with a spectral rolloff of f−4 Hz and noise floor of −20/−30 dB. While on station, the significant wave height estimates were comparable within 10%–15% among instrumentation. Discrepancies in the total energy and in the spectral shape between instruments arise when the ship is in motion. These differences can be quantified using the spectral behavior of the measurements, accounting for aliasing and Doppler corrections. The inertial sensors provided information on the amplitude of the ship’s modulation transfer function, which was estimated to be ~1.3 ± 0.2 while on station and increased while underway [2.1 at ship-over-ground (SOG) speed; 4.3 m s−1]. The correction scheme presented here is adequate for measurements collected at cruising speeds of 3 m s−1 or less. At speeds greater than 5 m s−1, the motion and Doppler corrections are not sufficient to correct the observed spectral degradation.

Published

2013

29. On the Exchange of Momentum over the Open Ocean

Author

Dean Vickers, Christopher W. Fairall, Robert A. Weller, Hans Hersbach, Venkata Jampana, Sebastien P. Bigorre, Scott D. Miller, James B. Edson, Albert J. Plueddemann, and Larry Mahrt

Subjects

Atmosphere, Drag coefficient, Momentum (technical analysis), Wind shear, Surface roughness, Environmental science, Wind stress, Covariance, Oceanography, Atmospheric sciences, Physics::Atmospheric and Oceanic Physics, Wind speed

Abstract

This study investigates the exchange of momentum between the atmosphere and ocean using data collected from four oceanic field experiments. Direct covariance estimates of momentum fluxes were collected in all four experiments and wind profiles were collected during three of them. The objective of the investigation is to improve parameterizations of the surface roughness and drag coefficient used to estimate the surface stress from bulk formulas. Specifically, the Coupled Ocean–Atmosphere Response Experiment (COARE) 3.0 bulk flux algorithm is refined to create COARE 3.5. Oversea measurements of dimensionless shear are used to investigate the stability function under stable and convective conditions. The behavior of surface roughness is then investigated over a wider range of wind speeds (up to 25 m s−1) and wave conditions than have been available from previous oversea field studies. The wind speed dependence of the Charnock coefficient α in the COARE algorithm is modified to , where m = 0.017 m−1 s and b = −0.005. When combined with a parameterization for smooth flow, this formulation gives better agreement with the stress estimates from all of the field programs at all winds speeds with significant improvement for wind speeds over 13 m s−1. Wave age– and wave slope–dependent parameterizations of the surface roughness are also investigated, but the COARE 3.5 wind speed–dependent formulation matches the observations well without any wave information. The available data provide a simple reason for why wind speed–, wave age–, and wave slope–dependent formulations give similar results—the inverse wave age varies nearly linearly with wind speed in long-fetch conditions for wind speeds up to 25 m s−1.

Published

2013

30. A Surface Mooring for Air–Sea Interaction Research in the Gulf Stream. Part II: Analysis of the Observations and Their Accuracies

Author

Sebastien P. Bigorre, J. Ware, James B. Edson, and Robert A. Weller

Subjects

Gulf Stream, Atmospheric Science, Observational error, Meteorology, Random error, Calibration, Environmental science, Mode water, Ocean Engineering, Covariance, Mooring, Remote sensing

Abstract

A surface mooring was deployed in the Gulf Stream for 15 months to investigate the role of air–sea interaction in mode water formation and other processes. The accuracies of the near-surface meteorological and oceanographic measurements are investigated. In addition, the impacts of these measurement errors on the estimation and study of the air–sea fluxes in the Gulf Stream are discussed. Pre- and postdeployment calibrations together with in situ comparison between shipboard and moored sensors supported the identification of biases due to sensor drifts, sensor electronics, and calibration errors. A postdeployment field study was used to further investigate the performance of the wind sensors. The use of redundant sensor sets not only supported the filling of data gaps but also allowed an examination of the contribution of random errors. Air–sea fluxes were also analyzed and computed from both Coupled Ocean–Atmosphere Response Experiment (COARE) bulk parameterization and using direct covariance measurements. The basic conclusion is that the surface buoy deployed in the Gulf Stream to support air–sea interaction research was successful, providing an improved 15-month record of surface meteorology, upper-ocean variability, and air–sea fluxes with known accuracies. At the same time, the coincident deployment of mean meteorological and turbulent flux sensors proved to be a successful strategy to certify the validity of the bulk formula fluxes over the midrange of wind speeds and to support further work to address the present shortcomings of the bulk formula methods at the low and high wind speeds.

Published

2013

31. Wave–induced Characteristics of Atmospheric Turbulence Flux Measurements

Author

Joachim Reuder, Martin Flügge, Mostafa Bakhoday Paskyabi, and James B. Edson

Subjects

Physics, air–sea flux, Drag coefficient, Momentum (technical analysis), Buoy, Momentum transfer, Flux, Sea state, eddy correlation, Atmospheric sciences, momentum flux, Wind speed, Energy(all), Drag, Motion correction, drag coefficient, motion correction, Physics::Atmospheric and Oceanic Physics

Abstract

In this paper, we present the air–sea flux of momentum obtained with the eddy correlation method applied to data measured from a moored discus buoy deployed approximately 600 m off a research Air Sea Interaction Tower at Martha’s Vineyard Coastal Observatory, Massachusetts during spring 2010. We discuss corrections to account for the wave–induced motion of buoy. Our analysis confirm that the neutral drag coefficient depends upon wave age and wind speed. The data scatter between wind and momentum stress in the low wind speed are significantly larger for those with higher wind speeds. Furthermore, the momentum transfer is investigated using a wave model with sea state dependent drag coefficient. This wave age dependent drag reveals fairly good agreement compared to the observed drag coefficient. publishedVersion

Published

2013

32. A Surface Mooring for Air–Sea Interaction Research in the Gulf Stream. Part I: Mooring Design and Instrumentation

Author

Jeffrey Lord, Sebastien P. Bigorre, J. Ware, James B. Edson, and Robert A. Weller

Subjects

Gulf Stream, Atmospheric Science, Oceanography, Meteorology, Surface wave, Drag, Environmental science, Flux system, Heat losses, Ocean Engineering, Mooring

Abstract

The design of a surface mooring for deployment in the Gulf Stream in the Mid-Atlantic Bight is described. The authors' goals were to observe the surface meteorology; upper-ocean variability; and air–sea exchanges of heat, freshwater, and momentum in and near the Gulf Stream during two successive 1-yr deployments. Of particular interest was quantifying these air–sea fluxes during wintertime events that carry cold, dry air from the land over the Gulf Stream. Historical current data and information about the surface waves were used to guide the design of the surface mooring. The surface buoy provided the platform for both bulk meteorological sensors and a direct covariance flux system. Redundancy in the meteorological sensors proved to be a largely successful strategy to obtain complete time series. Oceanographic instrumentation was limited in size by considerations of drag; and two current meters, three temperature–salinity recorders, and 15 temperature recorders were deployed. Deployment from a single-screw vessel in the Gulf Stream required a controlled-drift stern first over the anchor sites. The first deployment lasted the planned full year. The second deployment ended after 3 months when the mooring was cut by unknown means at a depth of about 3000 m. The mooring was at times in the core of the Gulf Stream, and a peak surface current of over 2.7 m s−1 was observed. The 15-month records of surface meteorology and air–sea fluxes captured the seasonal variability as well as several cold-air outbreaks; the peak observed heat loss was in excess of 1400 W m−2.

Published

2012

33. Large-Eddy Simulation of Moist Convection during a Cold Air Outbreak over the Gulf Stream

Author

James B. Edson and Eric D. Skyllingstad

Subjects

Convection, Atmospheric Science, Radiative flux, Boundary layer, Sea surface temperature, Radiative cooling, Climatology, Mode water, Environmental science, Outflow, Atmospheric sciences, Physics::Atmospheric and Oceanic Physics, Geostrophic wind

Abstract

Cold air outflow over the Gulf Stream is modeled using a cloud-resolving large-eddy simulation model with three classes of precipitation. Simulations are conducted in a quasi-Lagrangian framework using an idealized sounding and uniform geostrophic winds based on observations taken on 20 February 2007 as part of the World Climate Research Program Climate Variability and Predictability (CLIVAR) Mode Water Dynamics Experiment (CLIMODE) project. Two cases are considered, one with an increasing sea surface temperature (SST) representing the crossing of the Gulf Stream front, and a second case with constant SST. Cloud systems develop in the model with strong convective plumes that spread into regions of stratus clouds at the top of the boundary layer. Simulated boundary layer growth is forced by a combination of evaporative cooling at the cloud top, upward radiative flux, and mechanical entrainment of the overlying warmer and drier air. Constant growth of the boundary layer acts to maintain a near-constant water vapor level in the boundary layer, promoting high latent and sensible heat fluxes. Frictional surface drag is distributed throughout the boundary layer by convection, causing increased shear at the cloud top, qualitatively agreeing with observed sounding profiles. Overall, the frontal case develops stronger precipitation and turbulence in comparison with the constant SST case. A near-uniform stratocumulus layer and stronger radiative cooling are produced in the constant SST case, whereas the frontal case generates open cumuliform clouds with reduced cloud coverage. Cloud evolution in the frontal case is similar to the transition from stratocumulus to shallow cumulus observed in the subtropics, as cumuliform clouds enhance cloud-top entrainment and evaporation of stratus clouds.

Published

2009

34. Sensors for physical fluxes at the sea surface: energy, heat, water, salt

Author

Robert A. Weller, E. F. Bradley, Robin W. Pascal, James B. Edson, Christopher W. Fairall, Margaret J. Yelland, and Ian M. Brooks

Subjects

lcsh:GE1-350, Momentum (technical analysis), Radiometer, Meteorology, Flow (psychology), lcsh:Geography. Anthropology. Recreation, Fluid mechanics, Aerodynamics, Dissipation, Sea surface temperature, lcsh:G, Range (aeronautics), Environmental science, lcsh:Environmental sciences, Physics::Atmospheric and Oceanic Physics

Abstract

The current status of meteorological sensors used aboard ships and buoys for measurement of the air-sea fluxes of momentum, heat, and freshwater is reviewed. Methods of flux measurement by the bulk aerodynamic, inertial dissipation and eddy-correlation methods are considered; and areas identified where improvements are needed in measurement of the basic variables. In some cases, what is required is the transition from emergent to operational technology, in others new technologies are needed. Uncertainties in measured winds caused by flow distortion over the ship are discussed, and the possible role of computational fluid mechanics models to obtain corrections. Basic studies are also needed on the influence of waves and rain on the fluxes. The issues involved in the specification of sea surface temperature are described, and the relative merits of the available sensors are discussed. The improved capability of buoy-mounted systems will depend on the emergence of low-power instruments, and/or by increasing the available power capacity. Other issues covered include the continuing uncertainty about the performance of rain gauges and short-wave radiometers. Also, the requirements for new instruments to extend the range of observations to extreme wind conditions are outlined, and the latest developments in the measurement of aerosol fluxes by eddy-correlation are presented.

Published

2008

35. Investigations of Air-Sea Gas Exchange in the CoOP Coastal Air-Sea Chemical Exchange Project

Author

James B. Edson, Michael D. DeGrandpre, Wade R. McGillis, and Nelson M. Frew

Subjects

Oceanography, Meteorology, Chemical exchange, Environmental science, Redistribution (cultural anthropology)

Abstract

Author Posting. © Oceanography Society, 2008. This article is posted here by permission of Oceanography Society for personal use, not for redistribution. The definitive version was published in Oceanography 21, 4 (2008): 34-45.

Published

2008

36. Platform Motion Effects on Measurements of Turbulence and Air–Sea Exchange over the Open Ocean

Author

James B. Edson, Carl A. Friehe, Scott D. Miller, and Tihomir Hristov

Subjects

Atmospheric Science, Meteorology, Turbulence, Anemometer, Environmental science, Motion (geometry), Magnitude (mathematics), Wind stress, Ocean Engineering, Surface layer, Atmospheric sciences, Deep sea, Wind speed

Abstract

Platform motion contaminates turbulence statistics measured in the surface layer over the ocean and therefore adds uncertainty to the understanding and parameterization of air–sea exchange. A modification to the platform motion–correction procedure of Edson et al. is presented that explicitly accounts for misalignment between anemometers and motion sensors. The method is applied to a high-resolution dataset, including four levels of turbulence within 20 m of the ocean surface, measured over deep ocean waves using the stable research platform R/P FLIP. The average error magnitude of the air–sea momentum flux (wind stress) from the four sensors during a 6-day period (10-m wind speed 2–14 m s−1) was 15% ± 1%, and varied systematically with measurement height. Motion and sensor-mounting offsets caused wind stress to be underestimated by 15% at 18.1 m, 13% at 13.8 m, and 11% at 8.7 m, and to be overestimated by 3% at 3.5 m. Sensor misalignment contributed to one-third of the correction to the wind stress. The motion correction reduced some measured artifacts in the wind that could otherwise be interpreted in terms of air–sea interaction, such as the angle between wind and wind stress vectors, while other features remained in the corrected wind, such as apparent upward momentum transfer from ocean to the atmosphere during low wind. These results demonstrate the complex interaction between motion and wind turbulence, and reinforce the necessity to measure and correct for platform motion. Finally, it is shown that the effects of motion on wind stress measured using R/P FLIP are much smaller than in situ measurements made using a conventional research ship.

Published

2008

37. Measurements of Momentum and Heat Transfer across the Air–Sea Interface

Author

John H. Trowbridge, Gregory P. Gerbi, Albert J. Plueddemann, Janet J. Fredericks, Eugene A. Terray, and James B. Edson

Subjects

Momentum (technical analysis), Meteorology, Mixed layer, Turbulence, Momentum transfer, Breaking wave, Mechanics, Oceanography, Thermal diffusivity, Physics::Fluid Dynamics, Heat transfer, Physics::Atmospheric and Oceanic Physics, Geology, Langmuir circulation

Abstract

This study makes direct measurements of turbulent fluxes in the mixed layer in order to close heat and momentum budgets across the air–sea interface and to assess the ability of rigid-boundary turbulence models to predict mean vertical gradients beneath the ocean’s wavy surface. Observations were made at 20 Hz at nominal depths of 2.2 and 1.7 m in ∼16 m of water. A new method is developed to estimate the fluxes and the length scales of dominant flux-carrying eddies from cospectra at frequencies below the wave band. The results are compared to independent estimates of those quantities, with good agreement between the two sets of estimates. The observed temperature gradients were smaller than predicted by standard rigid-boundary closure models, consistent with the suggestion that wave breaking and Langmuir circulation increase turbulent diffusivity in the upper ocean. Similarly, the Monin–Obukhov stability function ϕh was smaller in the authors’ measurements than the stability functions used in rigid-boundary applications of the Monin–Obukhov similarity theory. The dominant horizontal length scales of flux-carrying turbulent eddies were found to be consistent with observations in the bottom boundary layer of the atmosphere and from laboratory experiments in three ways: 1) in statically unstable conditions, the eddy sizes scaled linearly with distance to the boundary; 2) in statically stable conditions, length scales decreased with increasing downward buoyancy flux; and 3) downwind length scales were larger than crosswind length scales.

Published

2008

38. Large-Eddy Simulations and Observations of Atmospheric Marine Boundary Layers above Nonequilibrium Surface Waves

Author

Peter P. Sullivan, James B. Edson, James C. McWilliams, and Tihomir Hristov

Subjects

Atmospheric Science, Boundary layer, Meteorology, Surface wave, Planetary boundary layer, Wave propagation, Wind wave, Mechanics, Surface layer, Physics::Atmospheric and Oceanic Physics, Geology, Swell, Large eddy simulation

Abstract

Winds and waves in marine boundary layers are often in an unsettled state when fast-running swell generated by distant storms propagates into local regions and modifies the overlying turbulent fields. A large-eddy simulation (LES) model with the capability to resolve a moving sinusoidal wave at its lower boundary is developed to investigate this low-wind/fast-wave regime. It is used to simulate idealized situations with wind following and opposing fast-propagating waves (swell), and stationary bumps. LES predicts momentum transfer from the ocean to the atmosphere for wind following swell, and this can greatly modify the turbulence production mechanism in the marine surface layer. In certain circumstances the generation of a low-level jet reduces the mean shear between the surface layer and the PBL top, resulting in a near collapse of turbulence in the PBL. When light winds oppose the propagating swell, turbulence levels increase over the depth of the boundary layer and the surface drag increases by a factor of 4 compared to a flat surface. The mean wind profile, turbulence variances, and vertical momentum flux are then dependent on the state of the wave field. The LES results are compared with measurements from the Coupled Boundary Layers Air–Sea Transfer (CBLAST) field campaign. A quadrant analysis of the momentum flux from CBLAST verifies a wave age dependence predicted by the LES solutions. The measured bulk drag coefficient CD then depends on wind speed and wave state. In situations with light wind following swell, CD is approximately 50% lower than values obtained from standard bulk parameterizations that have no sea state dependence. In extreme cases with light wind and persistent swell, CD < 0.

Published

2008

39. The Coupled Boundary Layers and Air–Sea Transfer Experiment in Low Winds

Author

Nelson M. Frew, Albert J. Williams, Jielun Sun, Djamal Khelif, Greg Gerbi, Robert A. Weller, John H. Trowbridge, Costas G. Helmis, Ming Li, Andrew T. Jessup, Tihomir Hristov, James B. Edson, Lian Shen, Larry Mahrt, Tom Farrar, Dean Vickers, Peter P. Sullivan, Qing Wang, Dick K. P. Yue, John Wilkin, Timothy P. Stanton, Albert J. Plueddemann, Haf Jonsson, Jerry Crescenti, Eric D. Skyllingstad, Timothy L. Crawford, Shouping Wang, Wade R. McGillis, and Christopher J. Zappa

Subjects

Winds--Measurement--Mathematical models, Atmospheric Science, Momentum (technical analysis), Field (physics), Meteorology, Wind stress, Boundary (topology), Breaking wave, Ocean-atmosphere interaction--Mathematical models, Forcing (mathematics), Physical oceanography, Oceanography, Atmospheric sciences, Wind speed, Boundary layer (Meteorology)--Mathematical models, Environmental science, Hydrology, Physics::Atmospheric and Oceanic Physics

Abstract

The Office of Naval Research's Coupled Boundary Layers and Air–Sea Transfer (CBLAST) program is being conducted to investigate the processes that couple the marine boundary layers and govern the exchange of heat, mass, and momentum across the air–sea interface. CBLAST-LOW was designed to investigate these processes at the low-wind extreme where the processes are often driven or strongly modulated by buoyant forcing. The focus was on conditions ranging from negligible wind stress, where buoyant forcing dominates, up to wind speeds where wave breaking and Langmuir circulations play a significant role in the exchange processes. The field program provided observations from a suite of platforms deployed in the coastal ocean south of Martha's Vineyard. Highlights from the measurement campaigns include direct measurement of the momentum and heat fluxes on both sides of the air–sea interface using a specially constructed Air–Sea Interaction Tower (ASIT), and quantification of regional oceanic variability over scales of O(1–104 mm) using a mesoscale mooring array, aircraft-borne remote sensors, drifters, and ship surveys. To our knowledge, the former represents the first successful attempt to directly and simultaneously measure the heat and momentum exchange on both sides of the air–sea interface. The latter provided a 3D picture of the oceanic boundary layer during the month-long main experiment. These observations have been combined with numerical models and direct numerical and large-eddy simulations to investigate the processes that couple the atmosphere and ocean under these conditions. For example, the oceanic measurements have been used in the Regional Ocean Modeling System (ROMS) to investigate the 3D evolution of regional ocean thermal stratification. The ultimate goal of these investigations is to incorporate improved parameterizations of these processes in coupled models such as the Coupled Ocean–Atmosphere Mesoscale Prediction System (COAMPS) to improve marine forecasts of wind, waves, and currents.

Published

2007

40. Winter Atmospheric Conditions over the Japan/East Sea: The Structure and Impact of Severe Cold-Air Outbreaks

Author

Alberto Scotti, Robert C. Beardsley, Djamal Khelif, Richard Limeburner, James B. Edson, Carl A. Friehe, Shuyi S. Chen, and Clive E. Dorman

Subjects

Climatology, Environmental science, Outbreak, Cold air, Oceanography, Atmospheric sciences

Published

2006

41. Bulk Parameterization of Air–Sea Fluxes: Updates and Verification for the COARE Algorithm

Author

E. F. Bradley, Jeffrey E. Hare, Andrey A. Grachev, James B. Edson, and Christopher W. Fairall

Subjects

Atmospheric Science, Roughness length, Mixing ratio, Scalar (physics), Surface finish, Stability (probability), Conserved quantity, Algorithm, Water vapor, Wind speed, Mathematics

Abstract

In 1996, version 2.5 of the Coupled Ocean–Atmosphere Response Experiment (COARE) bulk algorithm was published, and it has become one of the most frequently used algorithms in the air–sea interaction community. This paper describes steps taken to improve the algorithm in several ways. The number of iterations to solve for stability has been shortened from 20 to 3, and adjustments have been made to the basic profile stability functions. The scalar transfer coefficients have been redefined in terms of the mixing ratio, which is the fundamentally conserved quantity, rather than the measured water vapor mass concentration. Both the velocity and scalar roughness lengths have been changed. For the velocity roughness, the original fixed value of the Charnock parameter has been replaced by one that increases with wind speeds of between 10 and 18 m s−1. The scalar roughness length parameterization has been simplified to fit both an early set of NOAA/Environmental Technology Laboratory (ETL) experiments and...

Published

2003

42. A network-based telemetry architecture developed for the Martha's Vineyard Coastal Observatory

Author

James B. Edson, Wade R. McGillis, T. Austin, M. McElroy, C.W. Grant, R.A. Petitt, J. Ware, S.K. Hurst, and M. Purcell

Subjects

Shore, geography, Service (systems architecture), Engineering, geography.geographical_feature_category, Interface (Java), business.industry, Mechanical Engineering, Ocean Engineering, Environmental exposure, Environmental data, Observatory, Systems architecture, ComputerSystemsOrganization_SPECIAL-PURPOSEANDAPPLICATION-BASEDSYSTEMS, Electrical and Electronic Engineering, Architecture, Telecommunications, business

Abstract

Underwater observatories with real-time data and virtually unlimited power transmission capabilities compared to traditional oceanographic moorings are beginning to provide scientists with continuous access to the coastal and open ocean. However, for any coastal observatory to serve as a cost-effective system for the collection of long-term scientific and environmental data, it must have a simple, upgradeable power and telemetry system and an instrument interface that is compatible with existing standards. It must be designed for extended environmental exposure and ease of service to avoid high maintenance costs. Most importantly, the observatory must be accessible to all potential users, including students, scientists, engineers, and policy makers. This strategy was applied to the design of the Martha's Vineyard Coastal Observatory on the south shore of the island of Martha's Vineyard. The new facility, and in particular its system architecture, as developed by the Woods Hole Oceanographic Institution with support from the National Science Foundation, are described.

Published

2002

43. An Investigation of Turbulent Heat Exchange in the Subtropics

Author

James B. Edson

Subjects

Boundary layer, Geography, Meteorology, Heat flux, Mathematical model, Turbulence, Heat transfer, Madden–Julian oscillation, Heat transfer coefficient, Covariance, Atmospheric sciences, Physics::Atmospheric and Oceanic Physics

Abstract

The long-term goal is to improve our understanding of heat and moisture exchange in the tropics through direct estimates of the fluxes and their related mean variables. The flux of heat across the coupled boundary layers is primarily accomplished by small-scale processes that are parameterized in numerical models. The ultimate goal is to improve the Navy s predictive capabilities in the tropics through an improved understanding of the processes driving the Madden-Julian Oscillation (MJO).

Published

2014

44. Carbon dioxide flux techniques performed during GasEx-98

Author

John W. H. Dacey, James B. Edson, Wade R. McGillis, Rik Wanninkhof, J. Ware, Jeffrey E. Hare, and Christopher W. Fairall

Subjects

geography, geography.geographical_feature_category, Meteorology, General Chemistry, Partial pressure, Oceanography, Atmospheric sciences, Sink (geography), Wind speed, chemistry.chemical_compound, Water column, Flux (metallurgy), chemistry, Carbon dioxide, Environmental Chemistry, Environmental science, Seawater, Physics::Atmospheric and Oceanic Physics, Water vapor, Water Science and Technology

Abstract

A comprehensive study of air–sea interactions focused on improving the quantification of CO2 fluxes and gas transfer velocities was performed within a large open ocean CO2 sink region in the North Atlantic. This study, GasEx-98, included shipboard measurements of direct covariance CO2 fluxes, atmospheric CO2 profiles, atmospheric DMS profiles, water column mass balances of CO2, and measurements of deliberate SF6–3He tracers, along with air–sea momentum, heat, and water vapor fluxes. The large air–sea differences in partial pressure of CO2 caused by a springtime algal bloom provided high signals for accurate CO2 flux measurements. Measurements were performed over a wind speed range of 1–16 m s−1 during the three-week process study. This first comparison between the novel air-side and more conventional water column measurements of air–sea gas transfer show a general agreement between independent air–sea gas flux techniques. These new advances in open ocean air–sea gas flux measurements demonstrate the progress in the ability to quantify air–sea CO2 fluxes on short time scales. This capability will help improve the understanding of processes controlling the air–sea fluxes, which in turn will improve our ability to make regional and global CO2 flux estimates.

Published

2001

45. Direct covariance air-sea CO2fluxes

Author

Wade R. McGillis, James B. Edson, Jeffrey E. Hare, and Christopher W. Fairall

Subjects

Atmospheric Science, Ecology, Turbulence, Eddy covariance, Paleontology, Soil Science, Breaking wave, Forestry, Aquatic Science, Covariance, Oceanography, Wind speed, Geophysics, Flux (metallurgy), Space and Planetary Science, Geochemistry and Petrology, Climatology, Earth and Planetary Sciences (miscellaneous), Atmospheric instability, Environmental science, Astrophysics::Earth and Planetary Astrophysics, Surface layer, Physics::Atmospheric and Oceanic Physics, Earth-Surface Processes, Water Science and Technology

Abstract

Direct covariance air-sea CO2 flux measurements over the open ocean are reported. These measurements were performed during June 1998 in the North Atlantic within a significant CO2 sink. These direct estimates are in general agreement with the traditional geochemical isotope constraints. The covariance, or eddy correlation, technique directly measures the air-sea CO2 flux over hour timescales by correlating the fluctuations of CO2 with the turbulent vertical velocity fluctuations in the atmospheric surface layer. These measurements quantify the transfer of CO2 between the atmosphere and ocean over a range of wind speeds and improve the understanding of the environmental factors controlling the flux. The relatively large flux of CO2 in the study region, together with improved analytical techniques, facilitated the measurements. The half-hour mean wind speeds varied from 0.9 to 16.3 m s−1 over the month-long experiment. The mean pCO2 during the study period was −85.8±16.0 μatm, and the mean covariance CO2 flux was estimated at 4.6 mol m−2 yr−1. The average observed wind speed was 7.7 m s−1. This is in close agreement with 3.9 mol m−2 yr−1, the approximate CO2 flux based on 14C parameterizations at this wind speed. At high winds, where the relationship between gas physical properties, surface processes, and air-sea gas exchange is still elusive, direct CO2 flux measurements are crucial. The measurements for winds in excess of 11 m s−1 show a general enhancement of gas transfer velocity over previous indirect measurements, and it is believed that this enhancement can be explained by the fact that the indirect methods cannot discriminate surface process variability such as atmospheric stability, upper ocean mixing, wave age, wave breaking, or surface films.

Published

2001

46. Vertical Structure Of Turbulence In Offshore Flow During Rasex

Author

James M. Wilczak, Dean Vickers, Jeffrey E. Hare, Larry Mahrt, Jørgen Højstrup, and James B. Edson

Subjects

Atmospheric Science, Buoyancy, Meteorology, Turbulence, Advection, Planetary boundary layer, Stratification (water), Mechanics, engineering.material, Physics::Fluid Dynamics, Boundary layer, Warm front, Turbulence kinetic energy, engineering, Physics::Atmospheric and Oceanic Physics, Geology

Abstract

The adjustment of the boundary layer immediately downstream froma coastline is examined based on two levels of eddy correlation data collected on a mast at the shore and six levels of eddy correlation data and profiles of mean variables collected from a mast 2 km offshore during the Riso Air-Sea Experiment. The characteristics of offshore flow are studied in terms of case studies and inter-variable relationships for the entire one-month data set. A turbulent kinetic energy budget is constructed for each case study. The buoyancy generation of turbulence is small compared to shear generation and dissipation. However, weakly stable and weakly unstable cases exhibit completely different vertical structure. With flow of warm air from land over cooler water, modest buoyancy destruction of turbulence and reduced shear generation of turbulence over the less rough sea surface cause the turbulence to rapidly weaken downstream from the coast. The reduction of downward mixing of momentum by the stratification leads to smaller roughness lengths compared to the unstable case. Shear generation at higher levels and advection of stronger turbulence from land often lead to an increase of stress and turbulence energy with height and downward transport of turbulence energy toward the surface. With flow of cool air over a warmer sea surface, a convective internal boundary layer develops downstream from the coast. An overlying relatively thick layer of downward buoyancy flux (virtual temperature flux) is sometimes maintained by shear generation in the accelerating offshore flow.

Published

2001

47. Parameterization and Micrometeorological Measurement of Air–Sea Gas Transfer

Author

Wade R. McGillis, James B. Edson, Jeffrey E. Hare, and C. W. Fairaill

Subjects

Atmospheric Science, Field (physics), Gas transfer, Meteorology, Planetary boundary layer, Schmidt number, Eddy covariance, Environmental science, media_common.cataloged_instance, European union, Parametrization, Trace gas, media_common

Abstract

Because of the combination of smallconcentrations and/or small fluxes, the determinationof air–sea gas fluxes presents unusual measurementdifficulties. Direct measurements (i.e., eddycorrelation) of the fluxes are rarely attempted. Inthe last decade, there has been an intense scientificeffort to improve measurement techniques and to placebulk parameterizations of gas transfer on firmertheoretical grounds. Oceanic tracer experiments,near-surface mean concentration profiles, eddyaccumulation, and direct eddy covariance methods haveall been used. Theoretical efforts have focusedprimarily in the realm of characterizing the transferproperties of the oceanic molecular sublayer. Recentmajor field efforts organized by the U.S.A. (GASEX-98) andthe European Union (ASGAMAGE) have yielded atmospheric-derivedresults much closer to those from oceanographicmethods. In this paper, we review the physical basisof a bulk-to-bulk gas transfer parameterization thatis generalized for solubility and Schmidt number. Wealso discuss various aspects of recent sensor andtechnique developments used for direct measurementsand demonstrate experimental progress with resultsfrom ASGAMAGE and GASEX-98. It is clear that sensornoise, sensitivity, and cross talk with other speciesand even ship motion corrections still need improvement foraccurate measurements of trace gas exchange over theocean. Significant work remains to resolve issuesassociated with the effects of waves, bubbles, andsurface films.

Published

2000

48. Similarity Relationships in the Marine Atmospheric Surface Layer for Terms in the TKE and Scalar Variance Budgets*

Author

Christopher W. Fairall and James B. Edson

Subjects

Convection, Atmospheric Science, Meteorology, Turbulence, Scalar (physics), Mechanics, Dissipation, Physics::Fluid Dynamics, Momentum, Turbulence kinetic energy, Atmospheric instability, Environmental science, Physics::Atmospheric and Oceanic Physics, Dimensionless quantity

Abstract

Measurements of the momentum, heat, moisture, energy, and scalar variance fluxes are combined with dissipation estimates to investigate the behavior of marine surface layer turbulence. These measurements span a wide range of atmospheric stability conditions and provide estimates of z/L between −8 and 1. Second- and third-order velocity differences are first used to provide an estimate of the Kolmogorov constant equal to 0.53 ± 0.04. The fluxes and dissipation estimates are then used to provide Monin–Obukhov (MO) similarity relationships of the various terms in the turbulent kinetic energy (TKE) and scalar variance (SV) budgets. These relationships are formulated to have the correct limiting forms in extremely stable and convective conditions. The analyses concludes with a determination of updated dimensionless structure function parameters for use with the inertial–dissipation flux method. The production of TKE is found to balance its dissipation in convective conditions and to exceed dissipation...

Published

1998

49. Observation of Short Wind Waves in Coastal Waters*

Author

James B. Edson, Wade R. McGillis, Erik J. Bock, and Tetsu Hara

Subjects

Capillary wave, Meteorology, Infragravity wave, Wind wave, Wind stress, Gravity wave, Internal wave, Oceanography, Atmospheric sciences, Dispersion (water waves), Physics::Atmospheric and Oceanic Physics, Swell, Geology

Abstract

Observations of wind-generated gravity–capillary waves have been made during two recent field programs in coastal environments. The results of wave slope spectra on clean water show a well-defined correlation with the wind friction velocity. However, spectral values at higher wavenumbers (above 200 rad m−1) are significantly higher than previous laboratory results. In the presence of surface films wave spectra may decrease by more than one order of magnitude at lower wind stresses. The dispersion characteristics of short waves vary markedly depending on the wavenumber, the wind stress, and the surface chemical condition. Some results in the presence of surface films at intermediate winds show much higher apparent phase speeds than the theoretical dispersion relation. This may be because of an enhanced near-surface current or because of the relative increase of wave energy that is phase-locked to longer steep gravity waves.

Published

1998

50. Direct Covariance Flux Estimates from Mobile Platforms at Sea*

Author

Christopher W. Fairall, James B. Edson, Alan A. Hinton, K.E. Prada, and Jeffrey E. Hare

Subjects

Atmospheric Science, Tilt (optics), Anemometer, Distortion, Coordinate system, Flow (psychology), Ocean Engineering, Aerodynamics, Covariance, Geodesy, Rotation, Geology

Abstract

This paper describes two methods for computing direct covariance fluxes from anemometers mounted on moving platforms at sea. These methods involve the use of either a strapped-down or gyro-stabilized system that are used to compute terms that correct for the 1) instantaneous tilt of the anemometer due to the pitch, roll, and heading variations of the platform; 2) angular velocities at the anemometer due to rotation of the platform about its local coordinate system axes; and 3) translational velocities of the platform with respect to a fixed frame of reference. The paper provides a comparison of fluxes computed with three strapped-down systems from two recent field experiments. These comparisons shows that the direct covariance fluxes are in good agreement with fluxes derived using the bulk aerodynamic method. Additional comparisons between the ship system and the research platform FLIP indicate that flow distortion systematically increases the momentum flux by 15%. Evidence suggests that this correction is appropriate for a commonly used class of research vessels. The application of corrections for both motion contamination and flow distortion results in direct covariance flux estimates with an uncertainty of approximately 10%‐20%.

Published

1998