Carol stewart
[a School of Health Sciences, Massey University, PO Box 756, Wellington 6140, New Zealand]
David E. Damby
[b U.S. Geological Survey, Volcano Science Center, California Volcano Observatory, Menlo Park, CA, USA]
Ines Tomašek
[Institute of Hazard, Risk and Resilience, Department of Earth Sciences, Durham University, Durham, United Kingdom]
Claire J. Horwell
[c Institute of Hazard, Risk and Resilience, Department of Earth Sciences, Durham University, Durham, United Kingdom]
Geoffrey S. Plumlee
[U.S. Geological Survey, Reston, VA, USA]
Maria Aurora Armienta
[Universidad Nacional Autónoma de México, Instituto de Geofísica, México City, CDMX, Mexico]
Maria Gabriela Ruiz Hinojosa
[UCL]
Moya Appleby
[GNS Science, Wairakei, New Zealand]
Delmelle, Pierre
[UCL]
Shane Cronin
[School of Environment, University of Auckland, Private Bag 90, Auckland, New Zealand]
Christopher J. Ottley
[c Institute of Hazard, Risk and Resilience, Department of Earth Sciences, Durham University, Durham, United Kingdom]
Clive Oppenheimer
[Department of Geography, University of Cambridge, Cambridge, United Kingdom]
Suzette Morman
[U.S. Geological Survey, Denver Federal Center, Denver, CO, USA]
Volcanic ash presents a widespread and common hazard during and after eruptions. Complex interactions between solid ash surfaces and volcanic gases lead to the formation of soluble salts that may be mobilized in aqueous environments. A variety of stakeholders may be concerned about the effects of ash on human and animal health, drinking water supplies, crops, soils and surface runoff. As part of the immediate emergency response, rapid dissemination of information regarding potentially hazardous concentrations of soluble species is critical. However, substantial variability in the methods used to characterize leachable elements makes it challenging to compare datasets and eruption impacts. To address these challenges, the International Volcanic Health Hazard Network (www.ivhhn.org) organized a two-day workshop to define appropriate methods for hazard assessment. The outcome of this workshop was a ‘consensus protocol’ for analysis of volcanic ash samples for rapid assessment of hazards from leachable elements, which was subsequently ratified by leading volcanological organizations. The purpose of this protocol is to recommend clear, standard and reliable methods applicable to a range of purposes during eruption response, such as assessing impacts on drinking-water supplies and ingestion hazards to livestock, and also applicable to research purposes. Where possible, it is intended that the methods make use of commonly available equipment and require little training. To evaluate method transferability, an interlaboratory comparison exercise was organized among six laboratories worldwide. Each laboratory received a split of pristine ash, and independently analyzed it according to the protocol for a wide range of elements. Collated results indicate good repeatability and reproducibility for most elements, thus indicating that the development of this protocol is a useful step towards providing standardized and reliable methods for ash hazard characterization. In this article, we review recent ash leachate studies, report the outcomes of the comparison exercise and present a revised and updated protocol based on the experiences and recommendations of the exercise participants. The adoption of standardized methods will improve and facilitate the comparability of results among studies and enable the ongoing development of a global database of leachate information relevant for informing volcanic health hazards assessment.
Carol stewart ; David E. Damby ; Ines Tomašek ; Claire J. Horwell ; Geoffrey S. Plumlee ; et. al. Assessment of leachable elements in volcanic ashfall: a review and evaluation of a standardized protocol for ash hazard characterization. In: Philippine Journal of Volcanology, Vol. 392, p. 106756 (2020)