0000000000430682

AUTHOR

Ery C. Hughes

showing 3 related works from this author

Understanding Degassing Pathways Along the 1886 Tarawera (New Zealand) Volcanic Fissure by Combining Soil and Lake CO2 Fluxes

2019

CO2 flux measurements are often used to monitor volcanic systems, understand the cause of volcanic unrest, and map sub-surface structures. Currently, such measurements are incomplete at Tarawera (New Zealand), which erupted with little warning in 1886 and produced a ∼17 km long fissure. We combine new soil CO2 flux and C isotope measurements of Tarawera with previous data from Rotomahana and Waimangu (regions also along the 1886 fissure) to fingerprint the CO2 source, understand the current pathways for degassing, quantify the CO2 released along the entire fissure, and provide a baseline survey. The total CO2 emissions from the fissure are 1227 t⋅d–1 (742–3398 t⋅d–1 90 % confidence interval…

Carbon Isotopesgeographygeography.geographical_feature_categoryFissureTaraweraGeochemistryCo2 fluxSilicic:Geology [Science]Soil co2 fluxRotomahanaCurrent (stream)medicine.anatomical_structureVolcanocarbon isotopesmedicineGeneral Earth and Planetary SciencesCalderalcsh:QWaimangulcsh:ScienceCO2 fluxvolcanic degassingGeothermal gradientGeologyFrontiers in Earth Science
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Electron microprobe technique for the determination of iron oxidation state in silicate glasses

2018

We present a new calibration for the determination of the iron oxidation state in silicate glasses by electron probe microanalysis (EPMA) with the "flank method." This method is based on the changes in both intensity and wavelength of the FeLα and FeLβ X-ray emission lines with iron oxidation state. The flank method utilizes the maximum difference for the FeLα and FeLβ spectra observed at the peak flanks between different standard materials, which quantitatively correlates with the Fe2+ content. Provided that this correlation is calibrated on reference materials, the Fe2+/ΣFe ratio can be determined for samples with known total Fe content. Two synthetic Fe-rich ferric and ferrous garnet end…

MicroprobeMaterials science010504 meteorology & atmospheric sciencesInorganic chemistryElectron microprobe010502 geochemistry & geophysics01 natural sciencesRedoxflank methodferric-ferrous ratioGeophysicsGeochemistry and PetrologyOxidation stateredox statepillow glassesSilicate glassMicroprobesilicate glasses0105 earth and related environmental sciences
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High spatial resolution analysis of the iron oxidation state in silicate glasses using the electron probe

2018

The iron oxidation state in silicate melts is important for understanding their physical properties, although it is most often used to estimate the oxygen fugacity of magmatic systems. Often high spatial resolution analyses are required, yet the available techniques, such as μrXANES and μMössbauer, require synchrotron access. The flank method is an electron probe technique with the potential to measure Fe oxidation state at high spatial resolution but requires careful method development to reduce errors related to sample damage, especially for hydrous glasses. The intensity ratios derived from measurements on the flanks of FeLα and FeLβ X-rays (FeLβf/FeLαf) over a time interval (time-depend…

Dewey Decimal Classification::500 | Naturwissenschaften::540 | ChemieMaterials science010504 meteorology & atmospheric sciencesoxidationAnalytical chemistryreductionElectron010502 geochemistry & geophysics01 natural sciencesflank methodReduction (complexity)symbols.namesakeelectron beam damageGeochemistry and PetrologyOxidation stateElectron probe microanalysis (EPMA)High spatial resolutioniron (Fe) oxidation statesilicate glassSilicate glass0105 earth and related environmental sciencesGeophysicsddc:540Raman spectroscopysymbolsRaman spectroscopy
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