Presentation is loading. Please wait.

Presentation is loading. Please wait.

Dependence of spray flux on breaking waves Fairall, C AF: NOAA / ETL, 325 Broadway, Boulder, CO 80305 United States M.Banner and Morison, R The University.

Published byLoreen Nichols Modified over 9 years ago

Similar presentations

Presentation on theme: "Dependence of spray flux on breaking waves Fairall, C AF: NOAA / ETL, 325 Broadway, Boulder, CO 80305 United States M.Banner and Morison, R The University."— Presentation transcript:

1 Dependence of spray flux on breaking waves Fairall, C AF: NOAA / ETL, 325 Broadway, Boulder, CO 80305 United States M.Banner and Morison, R The University Of New South Wales, School of Mathematics, The University of New South Wales, Sydney, NSW 2052 Australia Peirson, W The University Of New South Wales, Civil Engineering, The University of New South Wales, Sydney, NSW 2052 Australia

2 Production and Removal at the sea-air interface Rate of change=Inputs-Removal=Source-Deposition For concentration n (#/volume) 1 Turbulent xport 2 Molecular diff. 3 Mean fall speed 4 Inertia 5 Source 1 2 3 4 5 Number(r)/m^2/sec HOWEVER: At least one additional piece of information is required to characterize the soure. *Initial ejection velocity Wej *Effective height h

3

4

5 Source function whitecap scaling: A single whitecap produces sea spray distribution s whitecap [r]

6 Scaling Arguments

7 Source Scaling with Forcing Forcing = –Whitecap fraction –U 3 –U * 3 –DE 2/3 –DE Energy going into wave breaking –Л(c) length of breaking waves per unit area

8 Droplet Source Functions h Sig wave height/2 P energy wave breaking σ surface tension r droplet radius η Kolmogorov microscale f fraction of P going into droplet production V f =droplet mean fall velocity Fairall et al. 1994 Fairall, Banner, Asher Physical Model

9 SPANDEX – SPUME Droplet Study Photograph of PDA and DMT probes for the Spray Production and Dynamics Experiment (Water Research Facility, Manly, Australia; January 2003). Bill Asher, Mike Banner, Chris Fairall, Bill Peirson

10 Droplet Source Strength: Deduced from droplet concentration data Above the source region, S n =0. Vertical transport balances fall velocity in equilibrium so constant=0 Within source region, S n ≈ V g n

11 Samples from Wind Tunnel Study SPANDEX Droplet spectra profiles Droplet spectra normalized by power law equation

12 Source Function Scaled by Friction Velocity Total near-surface droplet mass and the estimated mass flux near the surface (z=12.5 and 15.0 cm) as a function of u*. The SPANDEX data are indicated by circles. The red line represents the parameterization of Fairall et al. (1994) and the green solid line a recent update of that parameterization obtained from a physically-based model (Fairall et al., 2005).

13 Source Function Scaled by Small-Scale Wave Energy

Download ppt "Dependence of spray flux on breaking waves Fairall, C AF: NOAA / ETL, 325 Broadway, Boulder, CO 80305 United States M.Banner and Morison, R The University."

Similar presentations

Section 2: The Planetary Boundary Layer

Section 2: The Planetary Boundary Layer
Lecture 15: Capillary motion

Lecture 15: Capillary motion
NOAA COARE Gas Transfer parameterization: Update Using Wave Parameters C. W. Fairall* NOAA Earth Science Research Laboratory, Boulder, CO, USA Ludovic.

NOAA COARE Gas Transfer parameterization: Update Using Wave Parameters C. W. Fairall* NOAA Earth Science Research Laboratory, Boulder, CO, USA Ludovic.
Reading: Text, (p40-42, p49-60) Foken 2006 Key questions:

Reading: Text, (p40-42, p49-60) Foken 2006 Key questions:
Simulation of Cloud Droplets in Parameterized Shallow Cumulus During RICO and ICARTT Knut von Salzen 1, Richard Leaitch 2, Nicole Shantz 3, Jonathan Abbatt.

Simulation of Cloud Droplets in Parameterized Shallow Cumulus During RICO and ICARTT Knut von Salzen 1, Richard Leaitch 2, Nicole Shantz 3, Jonathan Abbatt.
Chapter 9 Solids and Fluids (c).

Chapter 9 Solids and Fluids (c).
MECH 221 FLUID MECHANICS (Fall 06/07) Chapter 9: FLOWS IN PIPE

MECH 221 FLUID MECHANICS (Fall 06/07) Chapter 9: FLOWS IN PIPE
1D SEDIMENT TRANSPORT MORPHODYNAMICS with applications to RIVERS AND TURBIDITY CURRENTS © Gary Parker November, 2004 1 CHAPTER 13: THE QUASI-STEADY APPROXIMATION.

1D SEDIMENT TRANSPORT MORPHODYNAMICS with applications to RIVERS AND TURBIDITY CURRENTS © Gary Parker November, CHAPTER 13: THE QUASI-STEADY APPROXIMATION.
Momentum flux across the sea surface

Momentum flux across the sea surface
1 Progress Towards Developing a Coupled Atmosphere-Wave-Ocean Framework for Research and Operational Hurricane Models Isaac Ginis B. Thomas, R. Yablonsky,

1 Progress Towards Developing a Coupled Atmosphere-Wave-Ocean Framework for Research and Operational Hurricane Models Isaac Ginis B. Thomas, R. Yablonsky,
Dr. Martin T. Auer MTU Department of Civil & Environmental Engineering ENVE5504 Surface Water Quality Modeling Lab 4. Mass Transport.

Dr. Martin T. Auer MTU Department of Civil & Environmental Engineering ENVE5504 Surface Water Quality Modeling Lab 4. Mass Transport.
Air-Sea Exchange : 2 SOEE3410 : Lecture 5 Ian Brooks.

Air-Sea Exchange : 2 SOEE3410 : Lecture 5 Ian Brooks.
Electrostatics #3 The Electric Field

Electrostatics #3 The Electric Field
GFS Deep and Shallow Cumulus Convection Schemes

GFS Deep and Shallow Cumulus Convection Schemes
Force Magnitude 1 Tension Elastic Force Gravity Normal Force Friction Drag.

Force Magnitude 1 Tension Elastic Force Gravity Normal Force Friction Drag.
Wind Driven Circulation I: Planetary boundary Layer near the sea surface.

Wind Driven Circulation I: Planetary boundary Layer near the sea surface.
Classical Mechanics Review 4: Units 1-19

Classical Mechanics Review 4: Units 1-19
Physics. Session Rotational Mechanics - 5 Session Objectives.

Physics. Session Rotational Mechanics - 5 Session Objectives.
Rolling. Rolling Condition – must hold for an object to roll without slipping.

Rolling. Rolling Condition – must hold for an object to roll without slipping.
Monin-Obukhoff Similarity Theory

Monin-Obukhoff Similarity Theory

Similar presentations

Ads by Google