Properties of Sarychev sulphate aerosols over the Arctic

Properties of Sarychev sulphate aerosols over the Arctic

Aerosols from the Sarychev Peak volcano entered the Arctic region less than a week after the strongest SO2eruption on June 15 and 16, 2009 and had, by the first week in July, spread out over the entire Arctic region. These predominantly stratospheric aerosols were determined to be sub‐micron in size...

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Veröffentlicht in:Journal of Geophysical Research: Atmospheres 2012-02, Vol.117 (D4), p.n/a
Hauptverfasser: O'Neill, N. T., Perro, C., Saha, A., Lesins, G., Duck, T. J., Eloranta, E. W., Nott, G. J., Hoffman, A., Karumudi, M. L., Ritter, C., Bourassa, A., Abboud, I., Carn, S. A., Savastiouk, V.
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Schlagworte:
Aerosols
Arctic zone
Atmospheric aerosols
Atmospheric research
Atmospheric sciences
Climate change
Earth
Earth sciences
Earth, ocean, space
Exact sciences and technology
fine mode effective radius
Geophysics
Lidar
Plumes
Remote sensing
Sarychev eruption
stratospheric optical depth
Sulfates
Sulfur dioxide
Tropopause
volcanic aerosols
Volcanoes
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container_issue D4
container_start_page
container_title Journal of Geophysical Research: Atmospheres
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creator O'Neill, N. T.
Perro, C.
Saha, A.
Lesins, G.
Duck, T. J.
Eloranta, E. W.
Nott, G. J.
Hoffman, A.
Karumudi, M. L.
Ritter, C.
Bourassa, A.
Abboud, I.
Carn, S. A.
Savastiouk, V.
description Aerosols from the Sarychev Peak volcano entered the Arctic region less than a week after the strongest SO2eruption on June 15 and 16, 2009 and had, by the first week in July, spread out over the entire Arctic region. These predominantly stratospheric aerosols were determined to be sub‐micron in size and inferred to be composed of sulphates produced from the condensation of SO2gases emitted during the eruption. Average (500 nm) Sarychev‐induced stratospheric optical depths (SOD) over the Polar Environmental Atmospheric Research Laboratory (PEARL) at Eureka (Nunavut, Canada) were found to be between 0.03 and 0.05 during the months of July and August, 2009. This estimate, derived from sunphotometry and integrated lidar backscatter profiles was consistent with averages derived from lidar estimates over Ny‐Ålesund (Spitsbergen). The Sarychev SOD e‐folding time at Eureka, deduced from lidar profiles, was found to be approximately 4 months relative to a regression start date of July 27. These profiles initially revealed the presence of multiple Sarychev plumes between the tropopause and about 17 km altitude. After about two months, the complex vertical plume structures had collapsed into fewer, more homogeneous plumes located near the tropopause. It was found that the noisy character of daytime backscatter returns induced an artifactual minimum in the temporal, pan‐Arctic, CALIOP SOD response to Sarychev sulphates. A depolarization ratio discrimination criterion was used to separate the CALIOP stratospheric layer class into a low depolarization subclass which was more representative of Sarychev sulphates. Post‐SAT (post Sarychev Arrival Time) retrievals of the fine mode effective radius (reff,f) and the logarithmic standard deviation for two Eureka sites and Thule (Greenland) were all close to 0.25 μm and 1.6 respectively. The stratospheric analogue to the columnar reff,f average was estimated to be reff,f(+) = 0.29 μm for Eureka data. Stratospheric, Raman lidar retrievals at Ny‐Ålesund, yielded a post‐SAT average of reff,f(+) = 0.27 μm. These results are ∼50% larger than the background stratospheric‐aerosol value. They are also about a factor of two larger than modeling values used in recent publications or about a factor of five larger in terms of (per particle) backscatter cross section. Key Points Stratospheric summer aerosols over the Arctic had effective radius ~0.28 um Stratospheric summertime AODs at 500 nm were between 0.03 and 0.05 The e‐folding times o
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T. ; Perro, C. ; Saha, A. ; Lesins, G. ; Duck, T. J. ; Eloranta, E. W. ; Nott, G. J. ; Hoffman, A. ; Karumudi, M. L. ; Ritter, C. ; Bourassa, A. ; Abboud, I. ; Carn, S. A. ; Savastiouk, V.</creator><creatorcontrib>O'Neill, N. T. ; Perro, C. ; Saha, A. ; Lesins, G. ; Duck, T. J. ; Eloranta, E. W. ; Nott, G. J. ; Hoffman, A. ; Karumudi, M. L. ; Ritter, C. ; Bourassa, A. ; Abboud, I. ; Carn, S. A. ; Savastiouk, V.</creatorcontrib><description>Aerosols from the Sarychev Peak volcano entered the Arctic region less than a week after the strongest SO2eruption on June 15 and 16, 2009 and had, by the first week in July, spread out over the entire Arctic region. These predominantly stratospheric aerosols were determined to be sub‐micron in size and inferred to be composed of sulphates produced from the condensation of SO2gases emitted during the eruption. Average (500 nm) Sarychev‐induced stratospheric optical depths (SOD) over the Polar Environmental Atmospheric Research Laboratory (PEARL) at Eureka (Nunavut, Canada) were found to be between 0.03 and 0.05 during the months of July and August, 2009. This estimate, derived from sunphotometry and integrated lidar backscatter profiles was consistent with averages derived from lidar estimates over Ny‐Ålesund (Spitsbergen). The Sarychev SOD e‐folding time at Eureka, deduced from lidar profiles, was found to be approximately 4 months relative to a regression start date of July 27. These profiles initially revealed the presence of multiple Sarychev plumes between the tropopause and about 17 km altitude. After about two months, the complex vertical plume structures had collapsed into fewer, more homogeneous plumes located near the tropopause. It was found that the noisy character of daytime backscatter returns induced an artifactual minimum in the temporal, pan‐Arctic, CALIOP SOD response to Sarychev sulphates. A depolarization ratio discrimination criterion was used to separate the CALIOP stratospheric layer class into a low depolarization subclass which was more representative of Sarychev sulphates. Post‐SAT (post Sarychev Arrival Time) retrievals of the fine mode effective radius (reff,f) and the logarithmic standard deviation for two Eureka sites and Thule (Greenland) were all close to 0.25 μm and 1.6 respectively. The stratospheric analogue to the columnar reff,f average was estimated to be reff,f(+) = 0.29 μm for Eureka data. Stratospheric, Raman lidar retrievals at Ny‐Ålesund, yielded a post‐SAT average of reff,f(+) = 0.27 μm. These results are ∼50% larger than the background stratospheric‐aerosol value. They are also about a factor of two larger than modeling values used in recent publications or about a factor of five larger in terms of (per particle) backscatter cross section. 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T.</creatorcontrib><creatorcontrib>Perro, C.</creatorcontrib><creatorcontrib>Saha, A.</creatorcontrib><creatorcontrib>Lesins, G.</creatorcontrib><creatorcontrib>Duck, T. J.</creatorcontrib><creatorcontrib>Eloranta, E. W.</creatorcontrib><creatorcontrib>Nott, G. J.</creatorcontrib><creatorcontrib>Hoffman, A.</creatorcontrib><creatorcontrib>Karumudi, M. L.</creatorcontrib><creatorcontrib>Ritter, C.</creatorcontrib><creatorcontrib>Bourassa, A.</creatorcontrib><creatorcontrib>Abboud, I.</creatorcontrib><creatorcontrib>Carn, S. A.</creatorcontrib><creatorcontrib>Savastiouk, V.</creatorcontrib><title>Properties of Sarychev sulphate aerosols over the Arctic</title><title>Journal of Geophysical Research: Atmospheres</title><addtitle>J. Geophys. Res</addtitle><description>Aerosols from the Sarychev Peak volcano entered the Arctic region less than a week after the strongest SO2eruption on June 15 and 16, 2009 and had, by the first week in July, spread out over the entire Arctic region. These predominantly stratospheric aerosols were determined to be sub‐micron in size and inferred to be composed of sulphates produced from the condensation of SO2gases emitted during the eruption. Average (500 nm) Sarychev‐induced stratospheric optical depths (SOD) over the Polar Environmental Atmospheric Research Laboratory (PEARL) at Eureka (Nunavut, Canada) were found to be between 0.03 and 0.05 during the months of July and August, 2009. This estimate, derived from sunphotometry and integrated lidar backscatter profiles was consistent with averages derived from lidar estimates over Ny‐Ålesund (Spitsbergen). The Sarychev SOD e‐folding time at Eureka, deduced from lidar profiles, was found to be approximately 4 months relative to a regression start date of July 27. These profiles initially revealed the presence of multiple Sarychev plumes between the tropopause and about 17 km altitude. After about two months, the complex vertical plume structures had collapsed into fewer, more homogeneous plumes located near the tropopause. It was found that the noisy character of daytime backscatter returns induced an artifactual minimum in the temporal, pan‐Arctic, CALIOP SOD response to Sarychev sulphates. A depolarization ratio discrimination criterion was used to separate the CALIOP stratospheric layer class into a low depolarization subclass which was more representative of Sarychev sulphates. Post‐SAT (post Sarychev Arrival Time) retrievals of the fine mode effective radius (reff,f) and the logarithmic standard deviation for two Eureka sites and Thule (Greenland) were all close to 0.25 μm and 1.6 respectively. The stratospheric analogue to the columnar reff,f average was estimated to be reff,f(+) = 0.29 μm for Eureka data. Stratospheric, Raman lidar retrievals at Ny‐Ålesund, yielded a post‐SAT average of reff,f(+) = 0.27 μm. These results are ∼50% larger than the background stratospheric‐aerosol value. They are also about a factor of two larger than modeling values used in recent publications or about a factor of five larger in terms of (per particle) backscatter cross section. Key Points Stratospheric summer aerosols over the Arctic had effective radius ~0.28 um Stratospheric summertime AODs at 500 nm were between 0.03 and 0.05 The e‐folding times of stratospheric aerosols were ~4 months</description><subject>Aerosols</subject><subject>Arctic zone</subject><subject>Atmospheric aerosols</subject><subject>Atmospheric research</subject><subject>Atmospheric sciences</subject><subject>Climate change</subject><subject>Earth</subject><subject>Earth sciences</subject><subject>Earth, ocean, space</subject><subject>Exact sciences and technology</subject><subject>fine mode effective radius</subject><subject>Geophysics</subject><subject>Lidar</subject><subject>Plumes</subject><subject>Remote sensing</subject><subject>Sarychev eruption</subject><subject>stratospheric optical depth</subject><subject>Sulfates</subject><subject>Sulfur dioxide</subject><subject>Tropopause</subject><subject>volcanic aerosols</subject><subject>Volcanoes</subject><issn>0148-0227</issn><issn>2169-897X</issn><issn>2156-2202</issn><issn>2169-8996</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2012</creationdate><recordtype>article</recordtype><sourceid>8G5</sourceid><sourceid>ABUWG</sourceid><sourceid>AFKRA</sourceid><sourceid>AZQEC</sourceid><sourceid>BENPR</sourceid><sourceid>CCPQU</sourceid><sourceid>DWQXO</sourceid><sourceid>GNUQQ</sourceid><sourceid>GUQSH</sourceid><sourceid>M2O</sourceid><recordid>eNqN0MtKxDAUBuAgCg7qzgcoiODC6snJpclSZ3S8oeIV3ISYpky1Tsek4-XtjYyIuBCzySLff8L5CVmlsEUB9TYCpUcDoFIxNUd6SIXMEQHnSQ8oVzkgFotkJcYHSIcLyYH2iDoP7cSHrvYxa6vs0oZ3N_IvWZw2k5HtfGZ9aGPbpNcXH7Ju5LOd4LraLZOFyjbRr3zdS-R6f--qf5CfnA0P-zsnuRWAkJcMqgIsKgWOWnZPvbDINJZSalaWTjDFSndfck5Ba11JBoyiK0phfSUYY0tkYzZ3EtrnqY-deaqj801jx76dRpN251Jyjep_VOhC6UTXftGHdhrGaZFPBenf1E5SmzPlUgcx-MpMQv2UKkro02nzs_TE17-G2uhsUwU7dnX8zqDQCrniybGZe60b__7nTHM0vBjQQipIqXyWqmPn375TNjwaWbBCmNvTobnZ7d8Nby7RHLMPeHmbWA</recordid><startdate>20120227</startdate><enddate>20120227</enddate><creator>O'Neill, N. 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T. ; Perro, C. ; Saha, A. ; Lesins, G. ; Duck, T. J. ; Eloranta, E. W. ; Nott, G. J. ; Hoffman, A. ; Karumudi, M. L. ; Ritter, C. ; Bourassa, A. ; Abboud, I. ; Carn, S. 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T.</au><au>Perro, C.</au><au>Saha, A.</au><au>Lesins, G.</au><au>Duck, T. J.</au><au>Eloranta, E. W.</au><au>Nott, G. J.</au><au>Hoffman, A.</au><au>Karumudi, M. L.</au><au>Ritter, C.</au><au>Bourassa, A.</au><au>Abboud, I.</au><au>Carn, S. A.</au><au>Savastiouk, V.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Properties of Sarychev sulphate aerosols over the Arctic</atitle><jtitle>Journal of Geophysical Research: Atmospheres</jtitle><addtitle>J. Geophys. Res</addtitle><date>2012-02-27</date><risdate>2012</risdate><volume>117</volume><issue>D4</issue><epage>n/a</epage><issn>0148-0227</issn><issn>2169-897X</issn><eissn>2156-2202</eissn><eissn>2169-8996</eissn><abstract>Aerosols from the Sarychev Peak volcano entered the Arctic region less than a week after the strongest SO2eruption on June 15 and 16, 2009 and had, by the first week in July, spread out over the entire Arctic region. These predominantly stratospheric aerosols were determined to be sub‐micron in size and inferred to be composed of sulphates produced from the condensation of SO2gases emitted during the eruption. Average (500 nm) Sarychev‐induced stratospheric optical depths (SOD) over the Polar Environmental Atmospheric Research Laboratory (PEARL) at Eureka (Nunavut, Canada) were found to be between 0.03 and 0.05 during the months of July and August, 2009. This estimate, derived from sunphotometry and integrated lidar backscatter profiles was consistent with averages derived from lidar estimates over Ny‐Ålesund (Spitsbergen). The Sarychev SOD e‐folding time at Eureka, deduced from lidar profiles, was found to be approximately 4 months relative to a regression start date of July 27. These profiles initially revealed the presence of multiple Sarychev plumes between the tropopause and about 17 km altitude. After about two months, the complex vertical plume structures had collapsed into fewer, more homogeneous plumes located near the tropopause. It was found that the noisy character of daytime backscatter returns induced an artifactual minimum in the temporal, pan‐Arctic, CALIOP SOD response to Sarychev sulphates. A depolarization ratio discrimination criterion was used to separate the CALIOP stratospheric layer class into a low depolarization subclass which was more representative of Sarychev sulphates. Post‐SAT (post Sarychev Arrival Time) retrievals of the fine mode effective radius (reff,f) and the logarithmic standard deviation for two Eureka sites and Thule (Greenland) were all close to 0.25 μm and 1.6 respectively. The stratospheric analogue to the columnar reff,f average was estimated to be reff,f(+) = 0.29 μm for Eureka data. Stratospheric, Raman lidar retrievals at Ny‐Ålesund, yielded a post‐SAT average of reff,f(+) = 0.27 μm. These results are ∼50% larger than the background stratospheric‐aerosol value. They are also about a factor of two larger than modeling values used in recent publications or about a factor of five larger in terms of (per particle) backscatter cross section. Key Points Stratospheric summer aerosols over the Arctic had effective radius ~0.28 um Stratospheric summertime AODs at 500 nm were between 0.03 and 0.05 The e‐folding times of stratospheric aerosols were ~4 months</abstract><cop>Washington, DC</cop><pub>Blackwell Publishing Ltd</pub><doi>10.1029/2011JD016838</doi><tpages>21</tpages><oa>free_for_read</oa></addata></record>
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identifier ISSN: 0148-0227
ispartof Journal of Geophysical Research: Atmospheres, 2012-02, Vol.117 (D4), p.n/a
issn 0148-0227
2169-897X
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2169-8996
language eng
recordid cdi_proquest_miscellaneous_1024664928
source Wiley Free Content; Wiley-Blackwell AGU Digital Library; Wiley Online Library All Journals; Alma/SFX Local Collection
subjects Aerosols
Arctic zone
Atmospheric aerosols
Atmospheric research
Atmospheric sciences
Climate change
Earth
Earth sciences
Earth, ocean, space
Exact sciences and technology
fine mode effective radius
Geophysics
Lidar
Plumes
Remote sensing
Sarychev eruption
stratospheric optical depth
Sulfates
Sulfur dioxide
Tropopause
volcanic aerosols
Volcanoes
title Properties of Sarychev sulphate aerosols over the Arctic
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