Wynn L. Eberhard scite author profile

[1] We demonstrate first measurements of the aerosol indirect effect using ground-based remote sensors at a continental US site. The response of nonprecipitating, icefree clouds to changes in aerosol loading is quantified in terms of a relative change in cloud-drop effective radius for a relative change in aerosol extinction under conditions of equivalent cloud liquid water path. This is done in a single column of air at a temporal resolution of 20 s (spatial resolution of $100 m). Cloud-drop effective radius is derived from a cloud radar and microwave radiometer. Aerosol extinction is measured below cloud base by a Raman lidar. Results suggest that aerosols associated with maritime or northerly air trajectories tend to have a stronger effect on clouds than aerosols associated with northwesterly trajectories that also have local influence. There is good correlation (0.67) between the cloud response and a measure of cloud turbulence.

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Doppler Lidar Measurement of Profiles of Turbulence and Momentum Flux

Eberhard¹,

Cupp²,

Healy³

1989

J. Atmos. Oceanic Technol.

115

106

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A Method for Determining Cirrus Cloud Particle Sizes Using Lidar and Radar Backscatter Technique

Intrieri

Stephens

Eberhard³

et al. 1993

J. Appl. Meteor.

103

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Estimations of atmospheric boundary layer fluxes and other turbulence parameters from Doppler lidar data

Gal-Chen¹,

Xu²,

Eberhard³

1992

J. Geophys. Res.

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Techniques for extraction of boundary layer parameters from measurements of a short pulse (≈0.4 μs) CO2 Doppler lidar (λ = 10.6 μm) are described. The lidar is operated by the National Oceanic and Atmospheric Administration (NOAA) Wave Propagation Laboratory (WPL). The measurements are those collected during the First International Satellite Land Surface Climatology Project (ISLSCP) Field Experiment (FIFE). The recorded radial velocity measurements have a range resolution of 150 m. With a pulse repetition rate of 20 Hz it is possible to perform scannings in two perpendicular vertical planes (x–z and y–z) in approximately 72 s. By continuously operating the lidar for about an hour, one can extract stable statistics of the radial velocities. Assuming that the turbulence is horizontally homogeneous, we have estimated the mean wind, its standard deviations, and the momentum fluxes. We have estimated the first, second, and, third moments of the vertical velocity from the vertically pointing beam. Spectral analysis of the radial velocities is also performed, from which (by examining the amplitude of the power spectrum at the inertial range) we have deduced the kinetic energy dissipation. Finally, using the statistical form of the Navier‐Stokes equations, the surface heat flux is derived as the residual balance between the vertical gradient of the third moment of the vertical velocity and the kinetic energy dissipation. With the exception of the vertically pointing beam an individual radial velocity estimate is accurate only to ±0.7 m s−1. Combining many measurements would normally reduce the error, provided that it is unbiased and uncorrelated. The nature of some of the algorithms, however, is such that biased and correlated errors may be generated even though the “raw” measurements are not. We have developed data processing procedures that eliminate bias and minimize error correlation. Once bias and error correlations are accounted for, the large sample size is shown to reduce the errors substantially. We show, for instance, that a single momentum flux estimate has an accuracy of ±2m2s−2, but when combined with other measurements, the error can be reduced to ±0.10 m2 s−2. The principal features of the derived turbulence statistics for two case studies (July 11, 1987, 1611–1710 UTC and 1729–1810 UTC) are as follows: The mean surface wind is from the south and has a speed of approximately 15 m s−1. There is a southerly jet 1 km above the surface. The wind in the direction normal to the surface wind becomes more westerly with height. The derived momentum fluxes in the mixed layer agree with the unfiltered airplane measurements. They are of the order of approximately 0.5 m2 s−2 near the surface and are retarding the southerly wind. At the stable layer, the momentum fluxes are countergradient; they remain negative even though the southerlies are diminishing with height and are concentrated in thin layers. By spectrally analyzing the vertical beam, we have identified the Brunt‐Väisälä frequency as the dominated frequency in...

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The Experimental Cloud Lidar Pilot Study (ECLIPS) for Cloud—Radiation Research

Platt¹,

Young²,

Carswell³

et al. 1994

Bull. Amer. Meteor. Soc.

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The Experimental Cloud Lidar Pilot Study (ECLIPS) was initiated to obtain statistics on cloud-base height, extinction, optical depth, cloud brokenness, and surface fluxes. Two observational phases have taken place, in October-December 1989 and April-July 1991, with intensive 30-day periods being selected within the two time intervals. Data are being archived at NASA Langley Research Center and, once there, are readily available to the international scientific community. This article describes the scale of the study in terms of its international involvement and in the range of data being recorded. Lidar observations of cloud height and backscatter coefficient have been taken from a number of ground-based stations spread around the globe. Solar shortwave and infrared longwave fluxes and infra-red beam radiance have been measured at the surface wherever possible. The observations have been tailored to occur around the overpass times of the NOAA weather satellites. This article describes in some detail the various retrieval methods used to obtain results on cloud-base height, extinction coefficient, and infrared emittance, paying particular attention to the uncertainties involved. The above methods are then illustrated by both model simulations and by selected results from various laboratories. The ECLIPS data are shown to represent a valuable resource for cloud parameter-izations in models and for model validations.

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Wynn L. Eberhard

First measurements of the Twomey indirect effect using ground‐based remote sensors

Doppler Lidar Measurement of Profiles of Turbulence and Momentum Flux

A Method for Determining Cirrus Cloud Particle Sizes Using Lidar and Radar Backscatter Technique

Estimations of atmospheric boundary layer fluxes and other turbulence parameters from Doppler lidar data

The Experimental Cloud Lidar Pilot Study (ECLIPS) for Cloud—Radiation Research

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