Your search keyword '"Tamsin A. Mather"' showing total 4 results

1. A comparison of satellite‐ and ground‐based measurements of SO2 emissions from Tungurahua volcano, Ecuador

Author

Brendan T. McCormick, Michael Herzog, Jian Yang, Marie Edmonds, Tamsin A. Mather, Simon A. Carn, Silvana Hidalgo, and Baerbel Langmann

Published

2014

2. A new parameterization of volcanic ash complex refractive index based on NBO/T and SiO2 content

Author

Tamsin A. Mather, Elisa Carboni, Roy G. Grainger, G. S. Prata, Lucy Ventress, and David M. Pyle

Subjects

Atmospheric Science, Geophysics, Space and Planetary Science, Content (measure theory), Earth and Planetary Sciences (miscellaneous), Mineralogy, Refractive index, Geology, Natural bond orbital, Volcanic ash

Abstract

Radiative transfer models used in remote sensing and hazard assessment of volcanic ash require knowledge of ash optical parameters. Here, we characterise the bulk and glass compositions of a representative suite of volcanic ash samples with known complex refractive indices (n + ik: where n is the real and k is the imaginary part). Using a linear regression model, we develop a new parameterization allowing the complex refractive index of volcanic ash to be estimated from ash SiO2 content or ratio of non-bridging oxygens to tetrahedrally-coordinated cations (NBO/T). At visible wavelengths, n correlates better with bulk than glass composition (both SiO2 and NBO/T), and k correlates better with SiO2 content than NBO/T. Over a broader spectral range (0.4–19 μm), bulk correlates better than glass composition, and NBO/T generally correlates better than SiO2 content for both parts of the refractive index. In order to understand the impacts of our new parameterization on satellite retrievals, we compared IASI satellite (wavelengths 3.62–15.5 μm) mass loading retrievals using our new approach with retrievals that assumed a generic (Eyjafjallajökull) ash refractive index. There are significant differences in mass loading using our calculated indices specific to ash type rather than a generic index. Where mass loadings increase, there is often improvement in retrieval quality (corresponding to cost function decrease). This new parameterization of refractive index variation with ash composition will help to improve remote sensing retrievals for the rapid identification of ash and quantitative analysis of mass loadings from satellite data on operational timescales.

Published

2018

3. Sources, size distribution, and downwind grounding of aerosols from Mount Etna

Author

Andrew G. Allen, David M. Pyle, Andrew J. S. McGonigle, Brian Davison, Pierre Delmelle, Salvatore Inguaggiato, Alessandro Aiuppa, Tamsin A. Mather, Nicole Bobrowski, and Clive Oppenheimer

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Particle number, Paleontology, Soil Science, Mineralogy, Forestry, Aquatic Science, Oceanography, Strombolian eruption, Plume, Aerosol, Geophysics, Impact crater, Volcano, Space and Planetary Science, Geochemistry and Petrology, Particle-size distribution, Earth and Planetary Sciences (miscellaneous), Panache, Environmental science, Earth-Surface Processes, Water Science and Technology

Abstract

The number concentrations and size distributions of aerosol particles >0.3 mm diameter were measured at the summit of Mount Etna and up to 10 km downwind from the degassing vents during July and August 2004. Aerosol number concentrations reached in excess of 9 106 L1 at summit vents, compared to 4–8 104 L1 in background air. Number concentrations of intermediate size particles were higher in emissions from the Northeast crater compared to other summit crater vents, and chemical composition measurements showed that Northeast crater aerosols contained a higher mineral cation content compared to those from Voragine or Bocca Nuova, attributed to Strombolian or gas puffing activity within the vent. Downwind from the summit the airborne plume was located using zenith sky ultraviolet spectroscopy. Simultaneous measurements indicated a coincidence of elevated ground level aerosol concentrations with overhead SO2, demonstrating rapid downward mixing of the plume onto the lower flanks of the volcano under certain meteorological conditions. At downwind sites the ground level particle number concentrations were elevated in all size fractions, notably in the 2.0–7.5 mm size range. These findings are relevant for assessing human health hazard and suggest that aerosol size distribution measurements may aid volcanic risk management.

Published

2006

4. Characterization and evolution of tropospheric plumes from Lascar and Villarrica volcanoes, Chile

Author

Clive Oppenheimer, David M. Pyle, Andrew J. S. McGonigle, V. I. Tsanev, Andrew G. Allen, and Tamsin A. Mather

Subjects

Atmospheric Science, Particle number, Soil Science, Mineralogy, Aquatic Science, Oceanography, Atmospheric sciences, chemistry.chemical_compound, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Cloud condensation nuclei, Sulfate aerosol, Sulfate, Earth-Surface Processes, Water Science and Technology, Effective radius, Ecology, Paleontology, Forestry, Aerosol, Geophysics, chemistry, Space and Planetary Science, Particle-size distribution, Environmental science, Particle size

Abstract

Chile, reveal that both are significant and sustained emitters of SO2 (28 and 3.7 kg s � 1 , respectively), HCl (9.6 and 1.3 kg s � 1 , respectively), HF (4.5 and 0.3 kg s � 1 , respectively) and near-source sulfate aerosol (0.5 and 0.1 kg s � 1 , respectively). Aerosol plumes are characterized by particle number fluxes (0.08–4.0 mm radius) of � 10 17 s � 1 (Lascar) and � 10 16 s � 1 (Villarrica), the majority of which will act as cloud condensation nuclei at supersaturations >0.1%. Impactor studies suggest that the majority of these particles contain soluble SO4� . Most aerosol size distributions were bimodal with maxima at radii of 0.1–0.2 mm and 0.7–1.5 mm. The mean particle effective radius (Reff) ranged from 0.1 to 1.5 mm, and particle size evolution during transport appears to be controlled by particle water uptake (Villarrica) or loss (Lascar) rather than sulfate production. INDEX TERMS: 0305 Atmospheric Composition and Structure: Aerosols and particles (0345, 4801); 0322 Atmospheric Composition and Structure: Constituent sources and sinks; 0365 Atmospheric Composition and Structure: Troposphere—composition and chemistry; 8409 Volcanology: Atmospheric effects (0370); 8494 Volcanology: Instruments and techniques; KEYWORDS: volcanoes, degassing, aerosol sulphur dioxide, sulphate, Llaima

Published

2004