Comparison of Aerosol Optical Properties and Water Vapor Among Ground and Airborne Lidars and Sun Photometers During TARFOX
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S. H. Melfi | B. Holben | L. Remer | D. Whiteman | E. Browell | S. Ismail | R. Ferrare | K. Evans | P. Russell | J. Livingston | P. Hobbs | B. Schmid | A. Smirnov | S. Kooi | V. Brackett | M. Clayton | G. Schwemmer | S. Melfi
[1] B. Holben,et al. Urban/industrial aerosol: Ground‐based Sun/sky radiometer and airborne in situ measurements , 1997 .
[2] A. Ansmann,et al. Measurement of atmospheric aerosol extinction profiles with a Raman lidar. , 1990, Optics letters.
[3] E. Browell,et al. LASE measurements of aerosol and water vapor profiles during TARFOX , 2000 .
[4] J. P. Bruce,et al. Climate change 1995 , 1996 .
[5] F. G. Fernald. Analysis of atmospheric lidar observations: some comments. , 1984, Applied optics.
[6] Didier Tanré,et al. Multi-band automatic sun and sky scanning radiometer system for measurement of aerosols , 1994 .
[7] M. McCormick,et al. Methodology for error analysis and simulation of lidar aerosol measurements. , 1979, Applied optics.
[8] S. H. Melfi,et al. Raman lidar system for the measurement of water vapor and aerosols in the Earth's atmosphere. , 1992, Applied optics.
[9] Tak Matsumoto,et al. Airborne Tracking Sunphotometer , 1987 .
[10] Edward V. Browell,et al. First Lidar Measurements of Water Vapor and Aerosols from a High-Altitude Aircraft , 1995, Optical Remote Sensing of the Atmosphere.
[11] P. Hobbs. An overview of the University of Washington airborne measurements and results from the Tropospheric Aerosol Radiative Forcing Observational Experiment (TARFOX) , 1999 .
[12] Y. Sasano,et al. Aerosol Optical Properties Inferred from Simultaneous Lidar, Aerosol-Counter, and Sunphotometer Measurements , 1990 .
[13] M. Andreae,et al. Uncertainty in Climate Change Caused by Aerosols , 1996, Science.
[14] A. Smirnov,et al. AERONET-a federated instrument network and data archive for aerosol Characterization , 1998 .
[15] J. Kiehl,et al. The Relative Roles of Sulfate Aerosols and Greenhouse Gases in Climate Forcing , 1993, Science.
[16] Beat Schmid,et al. Retrieving the vertical structure of the effective aerosol complex index of refraction from a combination of aerosol in situ and remote sensing measurements during TARFOX , 2000 .
[17] R. Ferrare,et al. Raman lidar measurements of aerosol extinction and backscattering 2. Derivation of aerosol real refractive index, single-scattering albedo, and humidification factor using Raman lidar , 1998 .
[18] D. Whiteman,et al. Comparison of measurements by the NASA/GSFC scanning raman lidar and the DOE/ARM CART raman lidar , 1998 .
[19] Beat Schmid,et al. Comparison of modeled and empirical approaches for retrieving columnar water vapor from solar transmittance measurements in the 0.94‐μm region , 1996 .
[20] J. Hansen,et al. Radiative forcing and climate response , 1997 .
[21] S. H. Melfi,et al. Raman lidar measurements of aerosol extinction and backscattering. 1. Methods and comparisons , 1998 .
[22] J. Ackermann. The Extinction-to-Backscatter Ratio of Tropospheric Aerosol: A Numerical Study , 1998 .
[23] James C. Barnes,et al. Development of the Lidar Atmospheric Sensing Experiment (LASE): An Advanced Airborne DIAL Instrument , 1997 .
[24] J. Veefkind,et al. Comparisons of LASE, aircraft, and satellite measurements of aerosol optical properties and water vapor during TARFOX , 2000 .
[25] Philip B. Russell,et al. Chemical apportionment of aerosol column optical depth off the mid‐Atlantic coast of the United States , 1997 .
[26] Yoram J. Kaufman,et al. Interannual variation of ambient aerosol characteristics on the east coast of the United States , 1999 .
[27] Oleg Dubovik,et al. Measurement of atmospheric optical parameters on U.S. Atlantic coast sites, ships, and Bermuda during TARFOX , 2000 .
[28] David N. Whiteman,et al. Raman lidar measurements of Pinatubo aerosols over southeastern Kansas during November-December 1991 , 1992 .
[29] P. Pilewskie,et al. Pinatubo and pre‐Pinatubo optical‐depth spectra: Mauna Loa measurements, comparisons, inferred particle size distributions, radiative effects, and relationship to lidar data , 1993 .
[30] J. Coakley,et al. Climate Forcing by Anthropogenic Aerosols , 1992, Science.
[31] B. Evans. Sensitivity of the backscatter/extinction ratio to changes in aerosol properties: implications for lidar. , 1988, Applied optics.
[32] Peter V. Hobbs,et al. Humidification factors for atmospheric aerosols off the mid‐Atlantic coast of the United States , 1999 .
[33] J. Klett. Stable analytical inversion solution for processing lidar returns. , 1981, Applied optics.
[34] Terry Deshler,et al. Five Years of Lidar Observations of the Pinatubo Eruption Cloud , 1997 .
[35] S. Kinne,et al. Aerosol-induced radiative flux changes off the United States mid-Atlantic coast: Comparison of values calculated from sunphotometer and in situ data with those measured by airborne pyranometer , 1999 .
[36] C. Whitlock,et al. Phase function, backscatter, extinction, and absorption for standard radiation atmosphere and El Chichon aerosol models at visible and near-infrared wavelengths , 1985 .
[37] Philip B. Russell,et al. Aerosol properties and radiative effects in the United States East Coast haze plume: An overview of the Tropospheric Aerosol Radiative Forcing Observational Experiment (TARFOX) , 1999 .
[38] N. S. Higdon,et al. LASE Validation Experiment , 1997 .
[39] David N. Whiteman,et al. A Comparison of Water Vapor Measurements Made by Raman Lidar and Radiosondes , 1995 .
[40] A. Ansmann,et al. Combined raman elastic-backscatter LIDAR for vertical profiling of moisture, aerosol extinction, backscatter, and LIDAR ratio , 1992 .
[41] Gerrit de Leeuw,et al. Inversion of lidar signals with the slope method. , 1993, Applied optics.