Characterization of respirable volcanic ash from the Soufrière Hills volcano, Montserrat, with implications for human health hazards

Volcanic ash, generated in the long-lived eruption of the Soufrière Hills volcano, Montserrat, is shown to contain respirable (sub-4 μm) particles and cristobalite, a crystalline silica polymorph. Respirable particles of cristobalite can cause silicosis, raising the possibility that volcanic ash is...

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Bibliographic Details
Published in:Bulletin of volcanology 2003-07, Vol.65 (5), p.346-362
Main Authors: HORWELL, C. J, SPARKS, R. S. J, BREWER, T. S, LLEWELLIN, E. W, WILLIAMSON, B. J
Format: Article
Language:English
Subjects:
Crystalline rocks
Dust
Earth sciences
Earth, ocean, space
Engineering and environment geology. Geothermics
Eolian deposits
Exact sciences and technology
Fines & penalties
Fractionation
Health hazards
Hills
Igneous and metamorphic rocks petrology, volcanic processes, magmas
Natural hazards: prediction, damages, etc
Occupational safety
Silica
Silicosis
Suspended particulate matter
Volcanic eruptions
Volcanoes
Volcanology
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Summary:Volcanic ash, generated in the long-lived eruption of the Soufrière Hills volcano, Montserrat, is shown to contain respirable (sub-4 μm) particles and cristobalite, a crystalline silica polymorph. Respirable particles of cristobalite can cause silicosis, raising the possibility that volcanic ash is a respiratory health hazard. This study considers some of the main factors which affect human exposure to respirable volcanic ash, namely, the composition and proportions of respirable ash, and the composition and concentrations of airborne suspended particulates. The composition, size distribution and proportion (by weight) of respirable particles in representative samples of the Soufrière Hills tephra (dome-collapse ash-fall deposits, dome-collapse pyroclastic-flow matrix, Vulcanian explosion ash and mixed ash) have been characterized. Dome-collapse ash-fall deposits are significantly richer in respirable particles (12 wt%) than the other tephra samples, in particular the matrices of dome-collapse pyroclastic-flow deposits (3 wt%). Within the respirable fraction, dome-collapse ash contains the highest proportion of crystalline silica particles (20-27 number%, of which 97 wt% is cristobalite), compared with other primary tephra types (0.4-5.6 number%). This enrichment of crystalline silica in the dome-collapse ash is most pronounced in the very fine particle fraction (sub-2 μm). The results are explained as being due to significant size fractionation during fragmentation of pyroclastic flows, resulting in a fines-depleted dome-collapse matrix and a fines-rich dome-collapse ash deposit. For all sample types, the sub-4 μm fraction comprises 45-55 wt% of the sub-10 μm fraction. Aeolian deposit, lahar deposit and airborne samples of suspended ash, collected on filters, were characterized. These samples show enrichment of crystalline silica in the respirable fraction (10-18 number%). The results are consistent with ash in the environment having a mixed origin but originating predominantly from dome-collapse eruptions. The reworked ash, however, contains low proportions of respirable ash (~3 wt%) compared to primary ash samples. The concentration of ash particles re-suspended by road vehicles on Montserrat is found to decrease exponentially with height above the ground, indicating higher exposure for children compared with adults: PM^sub 4^ concentration at 0.9 m (height of two-year-old child) is 3 times that at 1.8 m (adult height). The composition of the re-suspend
ISSN:0258-8900
1432-0819
DOI:10.1007/s00445-002-0266-6