A novel approach for the characterization of transport and optical properties of aerosol particles near sources – Part I: Measurement of particle backscatter coefficient maps with a scanning UV lidar
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Volker Wulfmeyer | Andreas Behrendt | Gerhard Lammel | Sandip Pal | V. Wulfmeyer | G. Lammel | A. Behrendt | S. Pal | M. Valdebenito | M B Álvaro Valdebenito
[1] Ian Lewis,et al. Proceedings of the SPIE , 2012 .
[2] Volker Wulfmeyer,et al. A novel approach for the characterisation of transport and optical properties of aerosol particles near sources – Part II: Microphysics–chemistry-transport model development and application , 2011 .
[3] P. Di Girolamo,et al. Observation of convection initiation processes with a suite of state‐of‐the‐art research instruments during COPS IOP 8b , 2010 .
[4] Volker Wulfmeyer,et al. Elastic-backscatter-lidar-based characterization of the convective boundary layer and investigation of related statistics , 2010 .
[5] Salvador Calvet,et al. Airborne particulate matter from livestock production systems: a review of an air pollution problem. , 2010, Environmental pollution.
[6] Volker Wulfmeyer,et al. Three-dimensional observations of atmospheric humidity with a scanning differential absorption Lidar , 2009, Remote Sensing.
[7] Marcus Radlach. A scanning eye-safe rotational Raman lidar in the ultraviolet for measurements of tropospheric temperature fields , 2009 .
[8] Annamaria Costa,et al. Definition of yearly emission factor of dust and greenhouse gases through continuous measurements in swine husbandry , 2009 .
[9] C. Kottmeier,et al. Observations of Kinematics and Thermodynamic Structure Surrounding a Convective Storm Cluster over a Low Mountain Range , 2009 .
[10] J. Machol,et al. Scanning tropospheric ozone and aerosol lidar with double-gated photomultipliers. , 2009, Applied optics.
[11] Bruce Denby,et al. Comparison of two data assimilation methods for assessing PM10 exceedances on the European scale , 2008 .
[12] Volker Wulfmeyer,et al. Four-Dimensional Variational Data Analysis of Water Vapor Raman Lidar Data and Their Impact on Mesoscale Forecasts , 2008 .
[13] D. I. Cooper,et al. Air-flow distortion and turbulence statistics near an animal facility , 2008 .
[14] V. Wulfmeyer,et al. Development of an eye-safe solid-state tunable laser transmitter in the 1.4-1.5 microm wavelength region based on Cr4+:YAG crystal for lidar applications. , 2008, Applied optics.
[15] V. Wulfmeyer,et al. Scanning rotational Raman lidar at 355 nm for the measurement of tropospheric temperature fields , 2007 .
[16] Scott M Spuler,et al. Raman shifter optimized for lidar at a 1.5 microm wavelength. , 2007, Applied optics.
[17] C. Kottmeier,et al. Multi-sensor measurements of a convective storm cluster over a low mountain range: adaptive observations during PRINCE , 2007 .
[18] Volker Wulfmeyer,et al. Four-Dimensional Variational Assimilation of Water Vapor Differential Absorption Lidar Data: The First Case Study within IHOP_2002 , 2006 .
[19] B. Wehner,et al. Transformation of Aerosol Chemical Properties due to Transport Over a City , 2005 .
[20] Andreas Behrendt,et al. Temperature Measurements with Lidar , 2005 .
[21] C. Weitkamp. Lidar, Range-Resolved Optical Remote Sensing of the Atmosphere , 2005 .
[22] Scott M Spuler,et al. Raman-shifted eye-safe aerosol lidar. , 2004, Applied optics.
[23] G. Lammel,et al. Aerosols Emitted from a Livestock Farm in Southern Germany , 2004 .
[24] Andreas Behrendt,et al. Combined Raman lidar for the measurement of atmospheric temperature, water vapor, particle extinction coefficient, and particle backscatter coefficient. , 2002, Applied optics.
[25] Britt A. Holmén,et al. Lidar-assisted measurement of PM10 emissions from agricultural tilling in California's San Joaquin Valley – Part II: emission factors , 2001 .
[26] Volker Wulfmeyer,et al. On the relationship between relative humidity and particle backscattering coefficient in the marine boundary layer determined with differential absorption lidar , 2000 .
[27] J. Ackermann. The Extinction-to-Backscatter Ratio of Tropospheric Aerosol: A Numerical Study , 1998 .
[28] T. Trickl,et al. [Emission of particulates from a pig farm with central air exhaust in the pig stall]. , 1998, DTW. Deutsche tierarztliche Wochenschrift.
[29] J. Hartung,et al. Concentrations and emissions of airborne dust in livestock buildings in Northern Europe , 1998 .
[30] Y. Sasano,et al. Tropospheric aerosol extinction coefficient profiles derived from scanning lidar measurements over Tsukuba, Japan, from 1990 to 1993. , 1996, Applied optics.
[31] Edwin W. Eloranta,et al. Convective boundary layer mean depths and cloud geometrical properties obtained from volume imaging lidar data , 1995 .
[32] V. Kovalev,et al. Sensitivity of the lidar solution to errors of the aerosol backscatter-to-extinction ratio: influence of a monotonic change in the aerosol extinction coefficient. , 1995, Applied optics.
[33] A. Bucholtz,et al. Rayleigh-scattering calculations for the terrestrial atmosphere. , 1995, Applied optics.
[34] N. Takeuchi,et al. Effects of misestimated far-end boundary values on two common lidar inversion solutions. , 1994, Applied optics.
[35] L R Bissonnette,et al. Sensitivity analysis of lidar inversion algorithms. , 1986, Applied optics.
[36] Y. Sasano,et al. Error caused by using a constant extinction/backscattering ratio in the lidar solution. , 1985, Applied optics.
[37] F. G. Fernald. Analysis of atmospheric lidar observations: some comments. , 1984, Applied optics.
[38] Y. Sasano,et al. Significance of the extinction/backscatter ratio and the boundary value term in the solution for the two-component lidar equation. , 1984, Applied optics.