Trends in volcanic degassing through eruption cycles: insights from satellite measurements

<p>Effective use of volcanic gas measurements for eruption forecasting and hazard mitigation at active volcanoes requires an understanding of long-term degassing behavior as context. Much recent progress has been made in quantifying global volcanic emissions of sulfur dioxide (SO<sub>2</sub>) and other gas species by expanding the coverage of ground-based sensor networks and through analysis of decadal-scale satellite datasets. Combined, these advances have provided valuable constraints on the magnitude and variability of SO<sub>2</sub> emissions at over 120 actively degassing volcanoes worldwide. Being less constrained by the style or location of volcanic activity, satellite measurements can provide greater insight into trends in volcanic degassing during eruption cycles. Here, we present an analysis of ~15 years of volcanic SO<sub>2</sub> measurements by the ultraviolet (UV) Ozone Monitoring Instrument (OMI) aboard NASA’s Aura satellite, focused on observed trends in SO<sub>2</sub> emissions spanning eruptions of varying magnitude. The Aura/OMI measurements have been used to estimate annual mean SO<sub>2</sub> emissions at ~100 volcanoes active between 2005 and 2020, around 80 of which erupted during the 15-year period. Superposed epoch analysis (SEA) of SO<sub>2</sub> emission trends for the erupting volcanoes (with eruption magnitudes ranging from Volcanic Explosivity Index [VEI] 2 to 4) provides evidence that volcanoes exhibiting higher levels of SO<sub>2</sub> emission in the years prior to eruption typically produce eruptions of lower magnitude, and vice versa. Post-eruptive SO<sub>2</sub> degassing exceeds pre-eruptive emissions for several years after eruptions with VEI 3-4 and may scale with eruption size; perhaps consistent with larger eruptions being supplied by larger magma intrusions which continue to degas in subsequent years. The SEA is most robust for eruptions of intermediate magnitude (VEI 3) which are the most common events in the recent global eruption record covered by the OMI measurements. Limited observations of larger eruptions (VEI 5+) suggest significant differences in degassing trends during these larger events. Future work will extend the satellite-based estimates of volcanic SO<sub>2</sub> emissions both forward and backward in time using other UV satellite instruments, generating longer records of SO<sub>2</sub> degassing (extending back to 1978 for the strongest volcanic sources of SO<sub>2</sub>) that will be used to further explore and constrain these relationships.  </p>