7 results on '"Laura E. Clor"'
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2. Multi-year high-frequency hydrothermal monitoring of selected high-threat Cascade Range volcanoes
- Author
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D. Bergfeld, S.A. Archfield, Laura E. Clor, Peter J. Kelly, Kurt R. Spicer, A. C. Newman, I. M. Crankshaw, Steven E. Ingebritsen, and William C. Evans
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geography ,geography.geographical_feature_category ,010504 meteorology & atmospheric sciences ,Context (language use) ,STREAMS ,Unrest ,010502 geochemistry & geophysics ,01 natural sciences ,Hydrothermal circulation ,Fumarole ,Geophysics ,Volcano ,Geochemistry and Petrology ,Geological survey ,Physical geography ,Baseline (configuration management) ,Geology ,0105 earth and related environmental sciences - Abstract
From 2009 to 2015 the U.S. Geological Survey (USGS) systematically monitored hydrothermal behavior at selected Cascade Range volcanoes in order to define baseline hydrothermal and geochemical conditions. Gas and water data were collected regularly at 25 sites on 10 of the highest-risk volcanoes in the Cascade Range. These sites include near-summit fumarole groups and springs/streams that show clear evidence of magmatic influence (high 3He/4He ratios and/or large fluxes of magmatic CO2 or heat). Site records consist mainly of hourly temperature and hydrothermal-flux data. Having established baseline conditions during a multiyear quiescent period, the USGS reduced monitoring frequency from 2015 to present. The archived monitoring data are housed at (doi:10.5066/F72N5088). These data (1) are suitable for retrospective comparison with other continuous geophysical monitoring data and (2) will provide context during future episodes of volcanic unrest, such that unrest-related variations at these thoroughly characterized sites will be more clearly recognizable. Relatively high-frequency year-round data are essential to achieve these objectives, because many of the time series reveal significant diurnal, seasonal, and inter-annual variability that would tend to mask unrest signals in the absence of baseline data. Here we characterize normal variability for each site, suggest strategies to detect future volcanic unrest, and explore deviations from background associated with recent unrest.
- Published
- 2018
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3. Causes of unrest at silicic calderas in the East African Rift: New constraints from InSAR and soil-gas chemistry at Aluto volcano, Ethiopia
- Author
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William Hutchison, Giovanni Chiodini, Laura E. Clor, David M. Pyle, Gezahegn Yirgu, Juliet Biggs, Elias Lewi, Stefano Caliro, Tobias Fischer, and Tamsin A. Mather
- Subjects
geography ,Rift ,geography.geographical_feature_category ,010504 meteorology & atmospheric sciences ,Earth science ,Silicic ,Subsidence ,Unrest ,010502 geochemistry & geophysics ,01 natural sciences ,Geophysics ,Volcano ,Geochemistry and Petrology ,East African Rift ,Caldera ,Geothermal gradient ,Geology ,0105 earth and related environmental sciences - Abstract
Restless silicic calderas present major geological hazards, and yet many also host significant untapped geothermal resources. In East Africa, this poses a major challenge, although the calderas are largely unmonitored their geothermal resources could provide substantial economic benefits to the region. Understanding what causes unrest at these volcanoes is vital for weighing up the opportunities against the potential risks. Here we bring together new field and remote sensing observations to evaluate causes of ground deformation at Aluto, a restless silicic volcano located in the Main Ethiopian Rift (MER). Interferometric Synthetic Aperture Radar (InSAR) data reveal the temporal and spatial characteristics of a ground deformation episode that took place between 2008 and 2010. Deformation time series reveal pulses of accelerating uplift that transition to gradual long-term subsidence, and analytical models support inflation source depths of ∼5 km. Gases escaping along the major fault zone of Aluto show high CO2 flux, and a clear magmatic carbon signature (CO2-δ13C of −4.2‰ to −4.5‰). This provides compelling evidence that the magmatic and hydrothermal reservoirs of the complex are physically connected. We suggest that a coupled magmatic-hydrothermal system can explain the uplift-subsidence signals. We hypothesize that magmatic fluid injection and/or intrusion in the cap of the magmatic reservoir drives edifice-wide inflation while subsequent deflation is related to magmatic degassing and depressurization of the hydrothermal system. These new constraints on the plumbing of Aluto yield important insights into the behavior of rift volcanic systems and will be crucial for interpreting future patterns of unrest.
- Published
- 2016
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4. The Lassen hydrothermal system
- Author
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D. Bergfeld, William C. Evans, Steven E. Ingebritsen, and Laura E. Clor
- Subjects
010504 meteorology & atmospheric sciences ,Silicic ,Induced seismicity ,010502 geochemistry & geophysics ,Earthquake swarm ,01 natural sciences ,Hydrothermal circulation ,Geophysics ,Heat flux ,Geochemistry and Petrology ,Magma ,Deglaciation ,Petrology ,Geomorphology ,Geothermal gradient ,Geology ,0105 earth and related environmental sciences - Abstract
The active Lassen hydrothermal system includes a central vapor-dominated zone or zones beneath the Lassen highlands underlain by ~240 °C high-chloride waters that discharge at lower elevations. It is the best-exposed and largest hydrothermal system in the Cascade Range, discharging 41 ± 10 kg/s of steam (~115 MW) and 23 ± 2 kg/s of high-chloride waters (~27 MW). The Lassen system accounts for a full 1/3 of the total high-temperature hydrothermal heat discharge in the U.S. Cascades (140/400 MW). Hydrothermal heat discharge of ~140 MW can be supported by crystallization and cooling of silicic magma at a rate of ~2400 km3/Ma, and the ongoing rates of heat and magmatic CO2 discharge are broadly consistent with a petrologic model for basalt-driven magmatic evolution. The clustering of observed seismicity at ~4–5 km depth may define zones of thermal cracking where the hydrothermal system mines heat from near-plastic rock. If so, the combined areal extent of the primary heat-transfer zones is ~5 km2, the average conductive heat flux over that area is >25 W/m2, and the conductive-boundary length
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- 2016
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5. Hydrothermal response to a volcano-tectonic earthquake swarm, Lassen, California
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Laura E. Clor, Paul A. Hsieh, David R. Shelly, Steven E. Ingebritsen, William C. Evans, and P.H. Seward
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geography ,geography.geographical_feature_category ,Swarm behaviour ,Aquifer ,Moment magnitude scale ,Volcano tectonic earthquake ,Unrest ,Earthquake swarm ,Hydrothermal circulation ,Geophysics ,Volcano ,General Earth and Planetary Sciences ,Seismology ,Geology - Abstract
The increasing capability of seismic, geodetic, and hydrothermal observation networks allows recognition of volcanic unrest that could previously have gone undetected, creating an imperative to diagnose and interpret unrest episodes. A November 2014 earthquake swarm near Lassen Volcanic National Park, California, which included the largest earthquake in the area in more than 60 years, was accompanied by a rarely observed outburst of hydrothermal fluids. Although the earthquake swarm likely reflects upward migration of endogenous H2O-CO2 fluids in the source region, there is no evidence that such fluids emerged at the surface. Instead, shaking from the modest sized (moment magnitude 3.85) but proximal earthquake caused near-vent permeability increases that triggered increased outflow of hydrothermal fluids already present and equilibrated in a local hydrothermal aquifer. Long-term, multiparametric monitoring at Lassen and other well-instrumented volcanoes enhances interpretation of unrest and can provide a basis for detailed physical modeling.
- Published
- 2015
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6. Diffuse degassing at Longonot volcano, Kenya:Implications for CO2 flux in continental rifts
- Author
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Juliet Biggs, Tobias Fischer, Laura E. Clor, Marie Edmonds, Wesley Koros, Risper Kandie, Charlotte Vye-Brown, G. Kianji, and Elspeth Robertson
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geography ,Rift ,geography.geographical_feature_category ,010504 meteorology & atmospheric sciences ,Earth science ,Geochemistry ,010502 geochemistry & geophysics ,Passive degassing ,01 natural sciences ,Volcanic CO2 ,Hydrothermal circulation ,Tectonics ,Geophysics ,Volcano ,Impact crater ,Geochemistry and Petrology ,East African Rift ,Magma ,Caldera ,Geology ,0105 earth and related environmental sciences - Abstract
Magma movement, fault structures and hydrothermal systems influence volatile emissions at rift volcanoes. Longonot is a Quaternary caldera volcano located in the southern Kenyan Rift, where regional extension controls recent shallow magma ascent. Here we report the results of a soil carbon dioxide (CO2) survey in the vicinity of Longonot volcano, as well as fumarolic gas compositions and carbon isotope data. The total non-biogenic CO2 degassing is estimated at − 1, and is largely controlled by crater faults and fractures close to the summit. Thus, recent volcanic structures, rather than regional tectonics, control fluid pathways and degassing. Fumarolic gases are characterised by a narrow range in carbon isotope ratios (δ13C), from − 4.7‰ to − 6.4‰ (vs. PDB) suggesting a magmatic origin with minor contributions from biogenic CO2. Comparison with other degassing measurements in the East African Rift shows that records of historical eruptions or unrest do not correspond directly to the magnitude of CO2 flux from volcanic centres, which may instead reflect the current size and characteristics of the subsurface magma reservoir. Interestingly, the integrated CO2 flux from faulted rift basins is reported to be an order of magnitude higher than that from any of the volcanic centres for which CO2 surveys have so far been reported.
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- 2016
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7. Volatile and N isotope chemistry of the Molucca Sea collision zone: Tracing source components along the Sangihe Arc, Indonesia
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David R. Hilton, Udi Hartono, Zachary D. Sharp, Laura E. Clor, and Tobias Fischer
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geography ,Accretionary wedge ,geography.geographical_feature_category ,Volcanic arc ,Subduction ,Geochemistry ,Obduction ,Tectonics ,Geophysics ,Geochemistry and Petrology ,Oceanic crust ,Island arc ,Molucca Sea Collision Zone ,Geology - Abstract
[1] Volcanic gases are sensitive indicators of subduction processes and are used to evaluate the contributions from various source components. Nitrogen isotope systematics in particular are a valuable tool for determining the fate of organic matter in subduction zones. We present the first arc-wide survey of trace gas chemistry and nitrogen isotope variations from the Sangihe Arc of northeastern Indonesia, where the narrow Molucca Sea Plate subducts beneath the Sangihe Arc to the west and the Halmahera Arc to the east. Relative volatile abundances and N isotopic compositions of volcanic gases show systematic along-arc variations. Northern volcanoes exhibit low N2/He ratios and δ15N values (northern minima 542 and −7.3‰, respectively), indicating minimal addition of sediment to source magmas. In contrast, the southern part of the arc is characterized by high N2/He and δ15N values (southern maxima 2000 and +2.1‰, respectively), consistent with greater sediment contributions in the formation of the magmas. These observations can be correlated with the complex tectonic setting of the region whereby oblique collision between the two arcs has caused sediment obduction, decoupling the accretionary wedges from the underlying oceanic plate. In the north, where the collision is more developed, the lack of trace gas and N isotope evidence of sedimentary inputs to the source of arc magmas is consistent with enhanced sediment decoupling. In the south, where collision and accretionary wedge decoupling are not yet taking place, sediments would presumably subduct normally, in agreement with higher N2/He and δ15N values. Awu volcano, at the northernmost extension of the arc, is anomalous and exhibits high N2/He (2852) coupled with low δ15N (−3.3‰). These values are suggestive of increased slab contribution in the northernmost arc, possibly by slab melting as collision stalls the progress of the subducting plate and allows it to become superheated.
- Published
- 2005
- Full Text
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