Search results for " Volcanic plumes"

showing 5 items of 5 documents

Lidar sounding of volcanic plumes

2013

ABSTRACT Accurate knowledge of gas composition in volcanic plumes has high scientific and societal value. On the one hand, it gives information on the geophysical processes taking place inside volcanos; on the other hand, it provides alert on possible eruptions. For this reasons, it has been suggested to monitor volcanic plumes by lidar. In particular, one of the aims of the FP7 ERC project BRIDGE is the measurement of CO 2 concentration in volcanic gases by differential absorption lidar. This is a very challenging task due to the harsh environment, the narrowness and weakness of the CO 2 absorption lines and the difficulty to procure a suitable laser source. This paper, after a review on r…

010504 meteorology & atmospheric sciencesAerosol load01 natural sciencesVolcanic plume010309 opticsVolcanic Gases0103 physical scienceseventGas compositionAbsorption (electromagnetic radiation)Water vapor0105 earth and related environmental sciencesRemote sensingevent.disaster_typeLidargeographygeography.geographical_feature_categoryAerosolDepth soundingLidarCarbon dioxideVolcano13. Climate actionAerosol load; Carbon dioxide; Differential absorption; Lidar; Volcanic plumes; Water vaporDifferential absorptionWater vaporGeologyLidar Technologies, Techniques, and Measurements for Atmospheric Remote Sensing IX
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The bridge volcanic LIdar-BILLI: A review of data collection and processing techniques in the Italian most hazardous volcanic areas

2020

Volcanologists have demonstrated that carbon dioxide (CO2) fluxes are precursors of volcanic eruptions. Controlling volcanic gases and, in particular, the CO2 flux, is technically challenging, but we can retrieve useful information from magmatic/geological process studies for the mitigation of volcanic hazards including air traffic security. Existing techniques used to probe volcanic gas fluxes have severe limitations such as the requirement of near-vent in situ measurements, which is unsafe for operators and deleterious for equipment. In order to overcome these limitations, a novel range-resolved DIAL-Lidar (Differential Absorption Light Detection and Ranging) has been developed as part of…

Volcanic hazards010504 meteorology & atmospheric sciences010502 geochemistry & geophysics01 natural scienceslcsh:TechnologyData processing techniquesWind speedBridge (nautical)Volcanic Gaseslcsh:ChemistryHazardous wasteGeneral Materials ScienceeventVolcanic eruptionsInstrumentationlcsh:QH301-705.50105 earth and related environmental sciencesRemote sensingFluid Flow and Transfer Processesevent.disaster_typeCO2 flux Data processing techniques DIAL-Lidar Volcanic eruptions Volcanic plumesgeographyData collectiongeography.geographical_feature_categorylcsh:TProcess Chemistry and TechnologyCO<sub>2</sub> fluxGeneral Engineeringlcsh:QC1-999Computer Science ApplicationsfluxLidarVolcanolcsh:Biology (General)lcsh:QD1-999lcsh:TA1-2040DIAL-LidarVolcanic plumesEnvironmental scienceCO2lcsh:Engineering (General). Civil engineering (General)lcsh:Physics
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Development of an active alkaline trap to determine acidic gas ratios in volcanic plumes: sampling technique and analytical methods

2012

alkaline trap volcanic plumesSettore GEO/08 - Geochimica E Vulcanologia
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Ozone depletion in tropospheric volcanic plumes

2010

We measured ozone (O3) concentrations in the atmospheric plumes of the volcanoes St. Augustine (1976), Mt. Etna (2004, 2009) and Eyjafjallajökull (2010) and found O3 to be strongly depleted compared to the background at each volcano. At Mt. Etna O3 was depleted within tens of seconds from the crater, the age of the St. Augustine plumes was on the order of hours, whereas the O3 destruction in the plume of Eyjafjallajökull was maintained in 1–9 day old plumes. The most likely cause for this O3 destruction are catalytic bromine reactions as suggested by a model that manages to reproduce the very early destruction of O3 but also shows that O3 destruction is ongoing for several days. Given the o…

ozone depletion volcanic plumes
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Ultraviolet imaging of volcanic plumes: A new paradigm in volcanology

2017

Ultraviolet imaging has been applied in volcanology over the last ten years or so. This provides considerably higher temporal and spatial resolution volcanic gas emission rate data than available previously, enabling the volcanology community to investigate a range of far faster plume degassing processes than achievable hitherto. To date, this has covered rapid oscillations in passive degassing through conduits and lava lakes, as well as puffing and explosions, facilitating exciting connections to be made for the first time between previously rather separate sub-disciplines of volcanology. Firstly, there has been corroboration between geophysical and degassing datasets at ≈1 Hz, expeditin…

volcanic plumes010504 meteorology & atmospheric sciencesLavaEarth scienceFlow (psychology)010502 geochemistry & geophysicsmedicine.disease_cause01 natural sciencesVolcanic plumeInterdisciplinary volcanology; Ultraviolet cameras; Volcanic plumes; Earth and Planetary Sciences (all)medicineinterdisciplinary volcanology0105 earth and related environmental sciencesgeographygeography.geographical_feature_categoryultraviolet cameraslcsh:QE1-996.5Gas releaseVolcanologyGeophysicsPlumelcsh:GeologyDynamic modelsVolcano13. Climate actionGeneral Earth and Planetary SciencesEarth and Planetary Sciences (all)GeologyUltravioletUltraviolet camera
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