Quantitative analysis of the 1981 and 2001 Etna flank eruptions: a contribution for future hazard evaluation and mitigation

Maria Marsella Maria Marsella,Cristina Proietti Cristina Proietti,Silvia Scifoni Silvia Scifoni,Mauro Coltelli Mauro Coltelli

doi:10.4401/ag-5334

Maria Marsella Maria Marsella, Cristina Proietti Cristina Proietti + Show 2 more

Open Access

https://doi.org/10.4401/ag-5334

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Abstract

Lava flows produced during Etna flank eruptions represent severe hazards for the nearby inhabited areas, which can be protected by adopting prompt mitigation actions, such as the building of diversion barriers. Lava diversion measures were attempted recently during the 1983, 1991-93, 2001 and 2002 Etna eruptions, although with different degrees of success. In addition to the complexity of barrier construction (due to the adverse physical conditions), the time available to successfully slow the advance of a lava flow depends on the lava effusion rate, which is not easily measurable. One method to estimate the average lava effusion rate over a specified period of time is based on a volumetric approach; i.e. the measurement of the volume changes of the lava flow over that period. Here, this has been compared to an approach based on thermal image processing, as applied to estimate the average effusion rates of lava flows during the 1981 and 2001 Etna eruptions. The final volumes were measured by the comparison of pre-eruption and post-eruption photogrammetric digital elevation models and orthophotographs. Lava volume growth during these eruptions was estimated by locating the flow-front positions from analyses of scientific papers and newspapers reports, as well as from helicopter photographs. The analyses of these two eruptions contribute to the understanding of the different eruptive mechanisms, highlighting the role of the peak effusion rate, which represents a critical parameter for planning of mitigation actions and for hazard evaluation.

Highlights

Mount Etna is characterized by intense volcanic activity at the summit area, this does not usually pose a danger to nearby inhabited areas
Most of the recent flank eruptions were characterized by low average lava effusion rates of relatively long durations; e.g. during the 1950-51, 1983, 1984, 1985, 1991-93, 2001 and 2002-03 eruptions
Recent studies have demonstrated that satellite effusion rate measurements can have margins of error of up to 50% [Harris et al 2007]

Summary

Introduction

Mount Etna is characterized by intense volcanic activity at the summit area, this does not usually pose a danger to nearby inhabited areas. The time-averaged discharge rates (TADRs) can be evaluated by applying topographic and photogrammetric techniques to extract digital elevation models (DEMs) during syn-eruption surveys In this way, it is possible to measure the lava volume growth over a known time span, from which the TADR can be evaluated. A volumetric approach was applied to reconstruct the geometrical evolution of the lava fields, and for post-event estimation of the TADR trends of the lava flows during the 1981 and 2001 eruptions. This approach is based on comparisons of pre-eruption and post-eruption topographic surfaces, which are obtained by applying digital aerial photogrammetric techniques. Reconstructed using various data sources, such as scientific papers, newspaper reports and photographs taken during the eruptions

Syn-eruption surveying techniques for volumetric TADR estimation

Findings

Conclusions