In situ and space‐based observations of the Kelud volcanic plume: The persistence of ash in the lower stratosphere

Abstract Volcanic eruptions are important causes of natural variability in the climate system at all time scales. Assessments of the climate impact of volcanic eruptions by climate models almost universally assume that sulfate aerosol is the only radiatively active volcanic material. We report satellite observations from the Cloud‐Aerosol Lidar with Orthogonal Polarization (CALIOP) on board the Cloud‐Aerosol Lidar and Infrared Pathfinder Satellite Observations (CALIPSO) satellite after the eruption of Mount Kelud (Indonesia) on 13 February 2014 of volcanic materials in the lower stratosphere. Using these observations along with in situ measurements with the Compact Optical Backscatter AerosoL Detector (COBALD) backscatter sondes and optical particle counters (OPCs) made during a balloon field campaign in northern Australia, we find that fine ash particles with a radius below 0.3 µm likely represented between 20 and 28% of the total volcanic cloud aerosol optical depth 3 months after the eruption. A separation of 1.5–2 km between the ash and sulfate plumes is observed in the CALIOP extinction profiles as well as in the aerosol number concentration measurements of the OPC after 3 months. The settling velocity of fine ash with a radius of 0.3 µm in the tropical lower stratosphere is reduced by 50% due to the upward motion of the Brewer‐Dobson circulation resulting a doubling of its lifetime. Three months after the eruption, we find a mean tropical clear‐sky radiative forcing at the top of the atmosphere from the Kelud plume near −0.08 W/m2 after including the presence of ash; a value ~20% higher than if sulfate alone is considered. Thus, surface cooling following volcanic eruptions could be affected by the persistence of ash and should be considered in climate simulations.

[1]  H. Treut,et al.  THE CALIPSO MISSION: A Global 3D View of Aerosols and Clouds , 2010 .

[2]  R. Neely,et al.  The Persistently Variable “Background” Stratospheric Aerosol Layer and Global Climate Change , 2011, Science.

[3]  T. Nagai,et al.  Backscattering linear depolarization ratio measurements of mineral, sea-salt, and ammonium sulfate particles simulated in a laboratory chamber. , 2010, Applied optics.

[4]  Larry W. Thomason,et al.  Tropical stratospheric aerosol layer from CALIPSO lidar observations , 2009 .

[5]  M. T. Osborn,et al.  Airborne lidar observations of the Pinatubo volcanic plume , 1992 .

[6]  A. Adriani,et al.  Comparison of various linear depolarization parameters measured by lidar. , 1999, Applied optics.

[7]  Jacques Pelon,et al.  An Advanced System to Monitor the 3D Structure of Diffuse Volcanic Ash Clouds , 2013 .

[8]  P. Hamill,et al.  The Life Cycle of Stratospheric Aerosol Particles , 1997 .

[9]  S. Carn,et al.  Stratospheric volcanic ash emissions from the 13 February 2014 Kelut eruption , 2015 .

[10]  C. Timmreck,et al.  Initial fate of fine ash and sulfur from large volcanic eruptions , 2009 .

[11]  A. Robock Volcanic eruptions and climate , 2000 .

[12]  Lidar observation of the stratospheric aerosol layer over Okinawa, Japan, after the Mt. Pinatubo volcanic eruption , 1993 .

[13]  H. Jäger,et al.  Lidar backscatter to extinction, mass and area conversions for stratospheric aerosols based on midlatitude balloonborne size distribution measurements , 2002 .

[14]  J. Hansen,et al.  Efficacy of climate forcings , 2005 .

[15]  K. Rosenlof Seasonal cycle of the residual mean meridional circulation in the stratosphere , 1995 .

[16]  V. Freudenthaler,et al.  The 16 April 2010 major volcanic ash plume over central Europe: EARLINET lidar and AERONET photometer observations at Leipzig and Munich, Germany , 2010 .

[17]  H. Jäger,et al.  Correction to “Lidar backscatter to extinction, mass and area conversions for stratospheric aerosols based on midlatitude balloonborne size distribution measurements” , 2003 .

[18]  Nobuo Sugimoto,et al.  Characteristics of dust aerosols inferred from lidar depolarization measurements at two wavelengths. , 2006, Applied optics.

[19]  Albert Ansmann,et al.  Ash and fine-mode particle mass profiles from EARLINET-AERONET observations over central Europe after the eruptions of the Eyjafjallajökull volcano in 2010 , 2011 .

[20]  R. Turco,et al.  The 1980 eruptions of Mount St. Helens: Physical and chemical processes in the stratospheric clouds , 1983 .

[21]  J. Vernier,et al.  Significant radiative impact of volcanic aerosol in the lowermost stratosphere , 2015, Nature Communications.

[22]  J. Pommereau,et al.  Major influence of tropical volcanic eruptions on the stratospheric aerosol layer during the last decade , 2011 .

[23]  P. Seifert,et al.  Correction to “Volcanic aerosol layers observed with multiwavelength Raman lidar over central Europe in 2008–2009” , 2010 .

[24]  P. B. Russell,et al.  Physical and optical properties of the Pinatubo volcanic aerosol: Aircraft observations with impactors and a Sun‐tracking photometer , 1994 .

[25]  Bryan J. Johnson,et al.  Balloonborne measurements of the Pinatubo aerosol size distribution and volatility at Laramie, Wyomi , 1992 .

[26]  K. Snetsinger,et al.  Effect of the eruption of El Chichon on stratospheric aerosol size and composition , 1983 .

[27]  Qiang Fu,et al.  Mean radiative energy balance and vertical mass fluxes in the equatorial upper troposphere and lower stratosphere , 2005 .

[28]  A. Ansmann,et al.  Volcanic aerosol layers observed with multiwavelength Raman lidar over central Europe in 2008–2009 , 2010 .

[29]  S. Hayashida,et al.  Lidar measurements of stratospheric aerosol content and depolarization ratios after the eruption of El Chichón volcano: measurements at Nagoya, Japan , 2012 .

[30]  Daniel M. Peters,et al.  Measurements of the complex refractive index of volcanic ash at 450, 546.7, and 650 nm , 2015 .

[31]  Josef Gasteiger,et al.  Characterization of the Eyjafjallajökull ash-plume by means of lidar measurements over the Munich EARLINET-site , 2010, Remote Sensing.

[32]  A. Bucholtz,et al.  Rayleigh-scattering calculations for the terrestrial atmosphere. , 1995, Applied optics.

[33]  J. Liley,et al.  Thirty years of in situ stratospheric aerosol size distribution measurements from Laramie, Wyoming (41°N), using balloon‐borne instruments , 2003 .

[34]  S. Carn,et al.  Satellite‐based constraints on explosive SO2 release from Soufrière Hills Volcano, Montserrat , 2010 .

[35]  N. Gillett,et al.  Surface response to stratospheric aerosol changes in a coupled atmosphere–ocean model , 2013 .

[36]  J. Worden,et al.  Radiative forcing due to enhancements in tropospheric ozone and carbonaceous aerosols caused by Asian fires during spring 2008 , 2012 .

[37]  Terry Deshler,et al.  Electron microscope studies of Mt. Pinatubo aerosol layers over Laramie, Wyoming during summer 1991 , 1992 .

[38]  Carl A. Mears,et al.  Volcanic contribution to decadal changes in tropospheric temperature , 2014 .

[39]  T. Deshler,et al.  Condensation nuclei measurements in the midlatitude (1982–2012) and Antarctic (1986–2010) stratosphere between 20 and 35 km , 2014 .

[40]  K. Bedka,et al.  Increase in upper tropospheric and lower stratospheric aerosol levels and its potential connection with Asian pollution , 2015, Journal of geophysical research. Atmospheres : JGR.

[41]  Albert Ansmann,et al.  Vertically resolved separation of dust and smoke over Cape Verde using multiwavelength Raman and polarization lidars during Saharan Mineral Dust Experiment 2008 , 2009 .

[42]  Zhaoyan Liu,et al.  CALIOP observations of the transport of ash from the Eyjafjallajökull volcano in April 2010 , 2012 .

[43]  Holger Vömel,et al.  Particle backscatter and relative humidity measured across cirrus clouds and comparison with microphysical cirrus modelling , 2012 .

[44]  Charles R. Trepte,et al.  Tropical stratospheric circulation deduced from satellite aerosol data , 1992, Nature.

[45]  U. Schumann,et al.  Airborne observations of the Eyjafjalla volcano ash cloud over Europe during air space closure in April and May 2010 , 2010 .

[46]  Y. Sasano,et al.  Stratospheric aerosol change in the early stage of volcanic disturbance by the Pinatubo Eruption observed over Tsukuba, Japan , 1993 .

[47]  C. Clerbaux,et al.  The 2011 Nabro eruption, a SO 2 plume height analysis using IASI measurements , 2013 .

[48]  Makiko Sato,et al.  Potential climate impact of Mount Pinatubo eruption , 1992 .

[49]  Peter V. Hobbs,et al.  Airborne measurements of particle and gas emissions from the 1990 volcanic eruptions of Mount Redoubt , 1991 .

[50]  S. Mossop Volcanic Dust Collected at an Altitude of 20 KM , 1964, Nature.

[51]  W. Grant,et al.  Ozone and Aerosol Changes During the 1991-1992 Airborne Arctic Stratospheric Expedition , 1993, Science.