K. D. Evans scite author profile

Satellite measurements of volcanic sulfur dioxide (SO 2 ) emissions can provide critical information for aviation hazard mitigation, particularly when ash detection techniques fail. Recent developments in space-based SO 2 monitoring are discussed, focusing on daily, global ultraviolet (UV) measurements by the Ozone Monitoring Instrument (OMI) on NASA's Aura satellite. OMI's high sensitivity to SO 2 permits long-range tracking of volcanic clouds in the upper troposphere and lower stratosphere (UTLS) and accurate mapping of their perimeters to facilitate avoidance. Examples from 2006 to 2007 include eruptions of Soufriere Hills (Montserrat), Rabaul (Papua New Guinea), Nyamuragira (DR Congo), and Jebel at Tair (Yemen). A tendency for some volcanic clouds to occupy the jet stream suggests an increased threat to aircraft that exploit this phenomenon. Synergy between NASA A-Train sensors such as OMI and the Atmospheric Infrared Sounder (AIRS) on the Aqua satellite can provide critical information on volcanic cloud altitude. OMI and AIRS SO 2 data products are being produced in near real-time for distribution to Volcanic Ash Advisory Centers (VAACs) via a NOAA website. Operational issues arising from these improved SO 2 measurements include the reliability of SO 2 as proxy for co-erupted ash, the duration of VAAC advisories for long-lived volcanic clouds, and the potential effects of elevated concentrations of SO 2 and sulfate aerosol in ash-poor clouds on aircraft and avionics (including cumulative effects after multiple inadvertent transits through dilute clouds). Further research is required in these areas. Aviation community assistance is sought through continued reporting of sulfurous odors or other indications of diffuse volcanic cloud encounters, in order to validate the satellite retrievals.

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Raman Lidar Measurements during the International H2O Project. Part I: Instrumentation and Analysis Techniques

Whiteman

Demoz

Rush

et al. 2006

104

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The NASA Goddard Space Flight Center (GSFC) Scanning Raman Lidar (SRL) participated in the International H2O Project (IHOP), which occurred in May and June 2002 in the midwestern part of the United States. The SRL received extensive optical modifications prior to and during the IHOP campaign that added new measurement capabilities and enabled unprecedented daytime water vapor measurements by a Raman lidar system. Improvements were also realized in nighttime upper-tropospheric water vapor measurements. The other new measurements that were added to the SRL for the IHOP deployment included rotational Raman temperature, depolarization, cloud liquid water, and cirrus cloud ice water content. In this first of two parts, the details of the operational configuration of the SRL during IHOP are provided along with a description of the analysis and calibration procedures for water vapor mixing ratio, aerosol depolarization, and cirrus cloud extinction-to-backscatter ratio. For the first time, a Raman water vapor lidar calibration is performed, taking full account of the temperature sensitivity of water vapor and nitrogen Raman scattering. Part II presents case studies that permit the daytime and nighttime error statistics to be quantified.

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Raman lidar measurements of aerosol extinction and backscattering: 1. Methods and comparisons

Ferrare¹,

Melfi²,

Whiteman³

et al. 1998

J. Geophys. Res.

117

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A Comparison of Water Vapor Measurements Made by Raman Lidar and Radiosondes

Ferrare¹,

Melfi²,

Whiteman³

et al. 1995

J. Atmos. Oceanic Technol.

109

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Raman lidar measurements of aerosol extinction and backscattering: 2. Derivation of aerosol real refractive index, single‐scattering albedo, and humidification factor using Raman lidar and aircraft size distribution measurements

Ferrare¹,

Melfi²,

Whiteman³

et al. 1998

J. Geophys. Res.

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K. D. Evans

Tracking volcanic sulfur dioxide clouds for aviation hazard mitigation

Raman Lidar Measurements during the International H2O Project. Part I: Instrumentation and Analysis Techniques

Raman lidar measurements of aerosol extinction and backscattering: 1. Methods and comparisons

A Comparison of Water Vapor Measurements Made by Raman Lidar and Radiosondes

Raman lidar measurements of aerosol extinction and backscattering: 2. Derivation of aerosol real refractive index, single‐scattering albedo, and humidification factor using Raman lidar and aircraft size distribution measurements

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