Airborne and Ground-Based Measurements Using a High-Performance Raman Lidar

Whiteman, David N.; Rush, Kurt; Rabenhorst, Scott D.; Welch, Wayne; Cadirola, Martin; McIntire, G.; Russo, Felicita; Adam, Mariana; Venable, D. D.; Connell, R.; Veselovskii, Igor; Forno, Ricardo; Mielke, B.; Stein, B.; Leblanc, Thierry; McDermid, Stuart; Vömel, H.

doi:10.1175/2010jtecha1391.1

Cited by 54 publications

(38 citation statements)

References 49 publications

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“…However, the SRL system having sustained major damage during transportation for MOHAVE-I, was replaced by the Atmospheric Laboratory for Validation, Interagency Collaboration, and Education (ALVICE) trailer. ALVICE contains an upgraded version of the Raman Airborne Spectroscopic Lidar (RASL) adapted for ground-based measurements (Whiteman et al, 2007(Whiteman et al, , 2010. The AT lidar had only minor modifications.…”

Section: The Mohave-ii Campaign (October 2007)mentioning

confidence: 99%

Ground-based water vapor raman lidar measurements up to the upper troposphere and lower stratosphere for long-term monitoring

2012

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Abstract. Recognizing the importance of water vapor in the upper troposphere and lower stratosphere (UTLS) and the scarcity of high-quality, long-term measurements, JPL began the development of a powerful Raman lidar in 2005 to try to meet these needs. This development was endorsed by the Network for the Detection of Atmospheric Composition Change (NDACC) and the validation program for the EOSAura satellite. In this paper we review the stages in the instrumental development, data acquisition and analysis, profile retrieval and calibration procedures of the lidar, as well as selected results from three validation campaigns: MOHAVE (Measurements of Humidity in the Atmosphere and Validation Experiments), MOHAVE-II, and MOHAVE 2009. In particular, one critical result from this latest campaign is the very good agreement (well below the reported uncertainties) observed between the lidar and the Cryogenic FrostPoint Hygrometer in the entire lidar range 3-20 km, with a mean bias not exceeding 2 % (lidar dry) in the lower troposphere, and 3 % (lidar moist) in the UTLS. Ultimately the lidar has demonstrated capability to measure water vapor profiles from ∼1 km above the ground to the lower stratosphere with a precision of 10 % or better near 13 km and below, and an estimated accuracy of 5 %. Since 2005, nearly 1000 profiles have been routinely measured, and since 2009, the profiles have typically reached 14 km for one-hour integration times and 1.5 km vertical resolution, and can reach 21 km for 6-h integration times using degraded vertical resolutions.These performance figures show that, with our present target of routinely running our lidar two hours per night, 4 nights per week, we can achieve measurements with a precision in the UTLS equivalent to that achieved if launching one CFH per month.

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Section: The Mohave-ii Campaign (October 2007)mentioning

confidence: 99%

Ground-based water vapor raman lidar measurements up to the upper troposphere and lower stratosphere for long-term monitoring

2012

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“…Airborne DIAL systems have demonstrated to be able to provide accurate water vapor measurements with a vertical resolution ~200-400 m and a horizontal resolution few hundred meters to few km [5]. Similar measurements are demonstrated by a large airborne Raman lidar focusing on profiling tropospheric aerosols and water vapor [6].…”

Section: Introductionmentioning

confidence: 80%

Airborne Raman Lidar and its Applications for Atmospheric Process Studies

Wang

Wechsler

Mahon

et al. 2016

EPJ Web of Conferences

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Although ground-base Raman lidars are widely used for atmospheric observations, the capabilities of airborne Raman lidar is not fully explored. Here we presented two recently developed airborne Raman lidar systems for the studies of atmospheric boundary layer process, aerosols, and clouds. The systems are briefly introduced. Observation examples are presented to illustrate the unique observational capabilities of airborne Raman lidar and their applications for atmospheric process studies.

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“…Both signals can be combined to a single signal with up to 5.5 orders of magnitude, when used with a suitable PMT [5][6][7].…”

Section: Transient Recordermentioning

confidence: 99%