Japan Geoscience Union Meeting 2023

Presentation information

[J] Oral

S (Solid Earth Sciences ) » S-CG Complex & General

[S-CG57] Catastrophic eruptions: Mechanism and impact of eruptions

Thu. May 25, 2023 1:45 PM - 3:00 PM 303 (International Conference Hall, Makuhari Messe)

convener:Satoshi Okumura(Division of Earth and Planetary Materials Science, Department of Earth Science, Graduate School of Science, Tohoku University), Fukashi Maeno(Earthquake Research Institute, University of Tokyo), Yujiro J. Suzuki(Earthquake Research Institute, The University of Tokyo), Chairperson:Satoshi Okumura(Division of Earth and Planetary Materials Science, Department of Earth Science, Graduate School of Science, Tohoku University), Yujiro J. Suzuki(Earthquake Research Institute, The University of Tokyo), Fukashi Maeno(Earthquake Research Institute, University of Tokyo)

2:30 PM - 2:45 PM

[SCG57-04] Climate-impacting volcanism reconstructed by ice core sulfate isotopologues

★Invited Papers

*Shohei Hattori1 (1.Nanjing University)

Keywords:Sulfate aerosols, Volcanic eruption, isotopologue, Mass-independent fractionation

Volcanoes influence climate through the generation of sulfate aerosols, however it is difficult to determine the climate impact of a specific historical eruption using proxy records. In the stratospheric eruptions, where volcanic sulfur dioxide (SO2) in a plume penetrates the stratosphere, the stratospheric sulfate aerosol (SSA) layer generated multiyear climate impacts by increasing the planet's albedo for more than a year. Sulfate records in ice cores provide a key record of volcanic activity. However, the concentration of sulfate in the ice core does not alone indicate the explosiveness of the event and, specifically, whether the plume reached the stratosphere. Thus, the history of volcanic activity and its connection to climate impact and/or other surface-environment effects are unknown.
Developments in isotopic techniques permit the detection of stratospheric eruptions in ice cores. The isotope ratios d33S, d34S, and d36S are mass-dependently related in the troposphere. Thus, the initial composition of SO2 emitted by a point volcanic source is mass-dependent (D33S = 0‰). In the stratosphere, sulfate obtains a mass-independent composition (D33S ≠ 0‰) as a result of photo-oxidation of SO2 by shortwave UV radiation that is unique to the stratosphere. Thus, the only cause of considerable D33S in a volcanic sulfate layer is the injection of sulfur gases into the stratosphere. In addition, the oxygen anomaly D17O reflects the oxidation of oxygen atoms from SO2 to sulfate in the atmosphere, which is another constraint on tropospheric/stratospheric volcanism.
In Gautier et al. (2018 Nature Comm.), a novel 2600-year history of stratospheric volcanic episodes based on these isotopic techniques was demonstrated using five ice cores from Dome C, Antarctica. To discover stratospheric volcanisms in different ice core sites and sulfate peaks, subsequent investigations also applied D33S measurements by the MC-ICP-MS method, which requires much smaller sample volumes. In the talk, I will provide an overview of these isotope approaches and their latest applications, as well as a discussion of the relationship between volcanism and the surface environment.