Flux measurements of explosive degassing using a yearlong hydroacoustic record at an erupting submarine volcano
Identifieur interne : 000038 ( Main/Exploration ); précédent : 000037; suivant : 000039Flux measurements of explosive degassing using a yearlong hydroacoustic record at an erupting submarine volcano
Auteurs : R. P. Dziak [États-Unis] ; E. T. Baker [États-Unis] ; A. M. Shaw [États-Unis] ; D. R. Bohnenstiehl [États-Unis] ; W. W. Chadwick Jr. [États-Unis] ; J. H. Haxel [États-Unis] ; H. Matsumoto [États-Unis] ; S. L. Walker [États-Unis]Source :
- Geochemistry, Geophysics, Geosystems [ 1525-2027 ] ; 2012-11.
Descripteurs français
- Wicri :
- topic : Géochimie, Géophysique.
English descriptors
- KwdEn :
- Acoustic, Acoustic observations, Acoustic pressure, Acoustic signal, Acoustic signals, Acoustic waves, Aiuppa, Atmospheric administration, Best estimate, Carbon dioxide, Carbon dioxide degassing, Chadwick, Chem, Continuous monitoring, Cumulative flux, Cumulative mass flux, Degassing, Different density, Diffuse degassing, Diffuse emission, Dioxide, Dziak, Early june, Embley, Emission rates, Eruption, Eruption cycle, Eruption style, Eruption vent, Eruptive, Eruptive activity, Eruptive vent, Etna, Excess ocean sound pressures, Excess pressure, Explosion intensity, Explosion pulses, Explosive activity, Explosive degassing, Explosive eruptions, Flux estimates, Flux measurements, Gassing, Geochem, Geochemistry, Geochemistry geophysics geosystems, Geol, Geophys, Geophysics, Geosystems, Geotherm, Health association, Homogeneous medium, Hydroacoustic, Hydroacoustic explosion records, Hydroacoustic monitoring, Hydroacoustic record, Hydrophone, Hydrophone deployment, Hydrophone mooring, Hydrophone record, Individual explosion pulses, Infrasound, Infrasound arrivals, Instrument response, Lett, Linear relationship, Magma, Magma column, Magmatic, Magmatic gases, Many volcanoes, Mariana, Marine resources studies, Mass flux, Mole ratio, Monowai submarine volcano, National oceanic, Nephelometric turbidity units, Ocean acoustics, Oregon state, Other submarine volcanoes, Pacaya volcano, Particle displacement, Particle motion, Particle velocity, Plume, Point source, Popocatepetl volcano, Quiescent volcanoes, Resing, Sand point, Seafloor, Shallow ocean, Slant range, Sound pressure levels, Sound velocity, Stromboli, Stromboli volcano, Strombolian, Strombolian explosions, Subaerial, Subaerial volcanoes, Subduction zones, Submarine arcs, Submarine volcano, Submarine volcano figure, Submarine volcanoes, Sulfur dioxide, Summit vent, Symonds, Time history, Total uncertainty, Turbidity, Volcanic, Volcanic eruptions, Volcanic explosions, Volcanic vent, Volcanism, Volcano, Volcano summit, Volcanol, Volumetric change, Vulcano island, Water column, Wave equation, Woods hole, Yearlong hydroacoustic record.
- Teeft :
- Acoustic, Acoustic observations, Acoustic pressure, Acoustic signal, Acoustic signals, Acoustic waves, Aiuppa, Atmospheric administration, Best estimate, Carbon dioxide, Carbon dioxide degassing, Chadwick, Chem, Continuous monitoring, Cumulative flux, Cumulative mass flux, Degassing, Different density, Diffuse degassing, Diffuse emission, Dioxide, Dziak, Early june, Embley, Emission rates, Eruption, Eruption cycle, Eruption style, Eruption vent, Eruptive, Eruptive activity, Eruptive vent, Etna, Excess ocean sound pressures, Excess pressure, Explosion intensity, Explosion pulses, Explosive activity, Explosive degassing, Explosive eruptions, Flux estimates, Flux measurements, Gassing, Geochem, Geochemistry, Geochemistry geophysics geosystems, Geol, Geophys, Geophysics, Geosystems, Geotherm, Health association, Homogeneous medium, Hydroacoustic, Hydroacoustic explosion records, Hydroacoustic monitoring, Hydroacoustic record, Hydrophone, Hydrophone deployment, Hydrophone mooring, Hydrophone record, Individual explosion pulses, Infrasound, Infrasound arrivals, Instrument response, Lett, Linear relationship, Magma, Magma column, Magmatic, Magmatic gases, Many volcanoes, Mariana, Marine resources studies, Mass flux, Mole ratio, Monowai submarine volcano, National oceanic, Nephelometric turbidity units, Ocean acoustics, Oregon state, Other submarine volcanoes, Pacaya volcano, Particle displacement, Particle motion, Particle velocity, Plume, Point source, Popocatepetl volcano, Quiescent volcanoes, Resing, Sand point, Seafloor, Shallow ocean, Slant range, Sound pressure levels, Sound velocity, Stromboli, Stromboli volcano, Strombolian, Strombolian explosions, Subaerial, Subaerial volcanoes, Subduction zones, Submarine arcs, Submarine volcano, Submarine volcano figure, Submarine volcanoes, Sulfur dioxide, Summit vent, Symonds, Time history, Total uncertainty, Turbidity, Volcanic, Volcanic eruptions, Volcanic explosions, Volcanic vent, Volcanism, Volcano, Volcano summit, Volcanol, Volumetric change, Vulcano island, Water column, Wave equation, Woods hole, Yearlong hydroacoustic record.
Abstract
The output of gas and tephra from volcanoes is an inherently disorganized process that makes reliable flux estimates challenging to obtain. Continuous monitoring of gas flux has been achieved in only a few instances at subaerial volcanoes, but never for submarine volcanoes. Here we use the first sustained (yearlong) hydroacoustic monitoring of an erupting submarine volcano (NW Rota‐1, Mariana arc) to make calculations of explosive gas flux from a volcano into the ocean. Bursts of Strombolian explosive degassing at the volcano summit (520 m deep) occurred at 1–2 min intervals during the entire 12‐month hydrophone record and commonly exhibited cyclic step‐function changes between high and low intensity. Total gas flux calculated from the hydroacoustic record is 5.4 ± 0.6 Tg a−1, where the magmatic gases driving eruptions at NW Rota‐1 are primarily H2O, SO2, and CO2. Instantaneous fluxes varied by a factor of ∼100 over the deployment. Using melt inclusion information to estimate the concentration of CO2 in the explosive gases as 6.9 ± 0.7 wt %, we calculate an annual CO2 eruption flux of 0.4 ± 0.1 Tg a−1. This result is within the range of measured CO2 fluxes at continuously erupting subaerial volcanoes, and represents ∼0.2–0.6% of the annual estimated output of CO2from all subaerial arc volcanoes, and ∼0.4–0.6% of the mid‐ocean ridge flux. The multiyear eruptive history of NW Rota‐1 demonstrates that submarine volcanoes can be significant and sustained sources of CO2 to the shallow ocean.
First continuous, yearlong record of an ongoing seafloor volcanic eruption Developed mathematical method to estimate volcanic gas flux from hydroacoustic data Used melt inclusion information to estimate carbon dioxide flux
Url:
DOI: 10.1029/2012GC004211
Affiliations:
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xml:lang="en"><term>Acoustic</term><term>Acoustic observations</term><term>Acoustic pressure</term><term>Acoustic signal</term><term>Acoustic signals</term><term>Acoustic waves</term><term>Aiuppa</term><term>Atmospheric administration</term><term>Best estimate</term><term>Carbon dioxide</term><term>Carbon dioxide degassing</term><term>Chadwick</term><term>Chem</term><term>Continuous monitoring</term><term>Cumulative flux</term><term>Cumulative mass flux</term><term>Degassing</term><term>Different density</term><term>Diffuse degassing</term><term>Diffuse emission</term><term>Dioxide</term><term>Dziak</term><term>Early june</term><term>Embley</term><term>Emission rates</term><term>Eruption</term><term>Eruption cycle</term><term>Eruption style</term><term>Eruption vent</term><term>Eruptive</term><term>Eruptive activity</term><term>Eruptive vent</term><term>Etna</term><term>Excess ocean sound pressures</term><term>Excess pressure</term><term>Explosion intensity</term><term>Explosion pulses</term><term>Explosive activity</term><term>Explosive degassing</term><term>Explosive eruptions</term><term>Flux estimates</term><term>Flux measurements</term><term>Gassing</term><term>Geochem</term><term>Geochemistry</term><term>Geochemistry geophysics geosystems</term><term>Geol</term><term>Geophys</term><term>Geophysics</term><term>Geosystems</term><term>Geotherm</term><term>Health association</term><term>Homogeneous medium</term><term>Hydroacoustic</term><term>Hydroacoustic explosion records</term><term>Hydroacoustic monitoring</term><term>Hydroacoustic record</term><term>Hydrophone</term><term>Hydrophone deployment</term><term>Hydrophone mooring</term><term>Hydrophone record</term><term>Individual explosion pulses</term><term>Infrasound</term><term>Infrasound arrivals</term><term>Instrument response</term><term>Lett</term><term>Linear relationship</term><term>Magma</term><term>Magma column</term><term>Magmatic</term><term>Magmatic gases</term><term>Many volcanoes</term><term>Mariana</term><term>Marine resources studies</term><term>Mass flux</term><term>Mole ratio</term><term>Monowai submarine volcano</term><term>National oceanic</term><term>Nephelometric turbidity units</term><term>Ocean acoustics</term><term>Oregon state</term><term>Other submarine volcanoes</term><term>Pacaya volcano</term><term>Particle displacement</term><term>Particle motion</term><term>Particle velocity</term><term>Plume</term><term>Point source</term><term>Popocatepetl volcano</term><term>Quiescent volcanoes</term><term>Resing</term><term>Sand point</term><term>Seafloor</term><term>Shallow ocean</term><term>Slant range</term><term>Sound pressure levels</term><term>Sound velocity</term><term>Stromboli</term><term>Stromboli volcano</term><term>Strombolian</term><term>Strombolian explosions</term><term>Subaerial</term><term>Subaerial volcanoes</term><term>Subduction zones</term><term>Submarine arcs</term><term>Submarine volcano</term><term>Submarine volcano figure</term><term>Submarine volcanoes</term><term>Sulfur dioxide</term><term>Summit vent</term><term>Symonds</term><term>Time history</term><term>Total uncertainty</term><term>Turbidity</term><term>Volcanic</term><term>Volcanic eruptions</term><term>Volcanic explosions</term><term>Volcanic vent</term><term>Volcanism</term><term>Volcano</term><term>Volcano summit</term><term>Volcanol</term><term>Volumetric change</term><term>Vulcano island</term><term>Water column</term><term>Wave equation</term><term>Woods hole</term><term>Yearlong hydroacoustic record</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Acoustic</term><term>Acoustic observations</term><term>Acoustic pressure</term><term>Acoustic signal</term><term>Acoustic signals</term><term>Acoustic waves</term><term>Aiuppa</term><term>Atmospheric administration</term><term>Best estimate</term><term>Carbon dioxide</term><term>Carbon dioxide degassing</term><term>Chadwick</term><term>Chem</term><term>Continuous monitoring</term><term>Cumulative flux</term><term>Cumulative mass flux</term><term>Degassing</term><term>Different density</term><term>Diffuse degassing</term><term>Diffuse emission</term><term>Dioxide</term><term>Dziak</term><term>Early june</term><term>Embley</term><term>Emission rates</term><term>Eruption</term><term>Eruption cycle</term><term>Eruption style</term><term>Eruption vent</term><term>Eruptive</term><term>Eruptive activity</term><term>Eruptive vent</term><term>Etna</term><term>Excess ocean sound pressures</term><term>Excess pressure</term><term>Explosion intensity</term><term>Explosion pulses</term><term>Explosive activity</term><term>Explosive degassing</term><term>Explosive eruptions</term><term>Flux estimates</term><term>Flux measurements</term><term>Gassing</term><term>Geochem</term><term>Geochemistry</term><term>Geochemistry geophysics geosystems</term><term>Geol</term><term>Geophys</term><term>Geophysics</term><term>Geosystems</term><term>Geotherm</term><term>Health association</term><term>Homogeneous medium</term><term>Hydroacoustic</term><term>Hydroacoustic explosion records</term><term>Hydroacoustic monitoring</term><term>Hydroacoustic record</term><term>Hydrophone</term><term>Hydrophone deployment</term><term>Hydrophone mooring</term><term>Hydrophone record</term><term>Individual explosion pulses</term><term>Infrasound</term><term>Infrasound arrivals</term><term>Instrument response</term><term>Lett</term><term>Linear relationship</term><term>Magma</term><term>Magma column</term><term>Magmatic</term><term>Magmatic gases</term><term>Many volcanoes</term><term>Mariana</term><term>Marine resources studies</term><term>Mass flux</term><term>Mole ratio</term><term>Monowai submarine volcano</term><term>National oceanic</term><term>Nephelometric turbidity units</term><term>Ocean acoustics</term><term>Oregon state</term><term>Other submarine volcanoes</term><term>Pacaya volcano</term><term>Particle displacement</term><term>Particle motion</term><term>Particle velocity</term><term>Plume</term><term>Point source</term><term>Popocatepetl volcano</term><term>Quiescent volcanoes</term><term>Resing</term><term>Sand point</term><term>Seafloor</term><term>Shallow ocean</term><term>Slant range</term><term>Sound pressure levels</term><term>Sound velocity</term><term>Stromboli</term><term>Stromboli volcano</term><term>Strombolian</term><term>Strombolian explosions</term><term>Subaerial</term><term>Subaerial volcanoes</term><term>Subduction zones</term><term>Submarine arcs</term><term>Submarine volcano</term><term>Submarine volcano figure</term><term>Submarine volcanoes</term><term>Sulfur dioxide</term><term>Summit vent</term><term>Symonds</term><term>Time history</term><term>Total uncertainty</term><term>Turbidity</term><term>Volcanic</term><term>Volcanic eruptions</term><term>Volcanic explosions</term><term>Volcanic vent</term><term>Volcanism</term><term>Volcano</term><term>Volcano summit</term><term>Volcanol</term><term>Volumetric change</term><term>Vulcano island</term><term>Water column</term><term>Wave equation</term><term>Woods hole</term><term>Yearlong hydroacoustic record</term></keywords><keywords scheme="Wicri" type="topic" xml:lang="fr"><term>Géochimie</term><term>Géophysique</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract">The output of gas and tephra from volcanoes is an inherently disorganized process that makes reliable flux estimates challenging to obtain. Continuous monitoring of gas flux has been achieved in only a few instances at subaerial volcanoes, but never for submarine volcanoes. Here we use the first sustained (yearlong) hydroacoustic monitoring of an erupting submarine volcano (NW Rota‐1, Mariana arc) to make calculations of explosive gas flux from a volcano into the ocean. Bursts of Strombolian explosive degassing at the volcano summit (520 m deep) occurred at 1–2 min intervals during the entire 12‐month hydrophone record and commonly exhibited cyclic step‐function changes between high and low intensity. Total gas flux calculated from the hydroacoustic record is 5.4 ± 0.6 Tg a−1, where the magmatic gases driving eruptions at NW Rota‐1 are primarily H2O, SO2, and CO2. Instantaneous fluxes varied by a factor of ∼100 over the deployment. Using melt inclusion information to estimate the concentration of CO2 in the explosive gases as 6.9 ± 0.7 wt %, we calculate an annual CO2 eruption flux of 0.4 ± 0.1 Tg a−1. This result is within the range of measured CO2 fluxes at continuously erupting subaerial volcanoes, and represents ∼0.2–0.6% of the annual estimated output of CO2from all subaerial arc volcanoes, and ∼0.4–0.6% of the mid‐ocean ridge flux. The multiyear eruptive history of NW Rota‐1 demonstrates that submarine volcanoes can be significant and sustained sources of CO2 to the shallow ocean.</div><div type="abstract">First continuous, yearlong record of an ongoing seafloor volcanic eruption Developed mathematical method to estimate volcanic gas flux from hydroacoustic data Used melt inclusion information to estimate carbon dioxide flux</div></front></TEI><affiliations><list><country><li>États-Unis</li></country></list><tree><country name="États-Unis"><noRegion><name sortKey="Dziak, R P" sort="Dziak, R P" uniqKey="Dziak R" first="R. P." last="Dziak">R. P. Dziak</name></noRegion><name sortKey="Baker, E T" sort="Baker, E T" uniqKey="Baker E" first="E. T." last="Baker">E. T. Baker</name><name sortKey="Bohnenstiehl, D R" sort="Bohnenstiehl, D R" uniqKey="Bohnenstiehl D" first="D. R." last="Bohnenstiehl">D. R. Bohnenstiehl</name><name sortKey="Chadwick Jr, W W" sort="Chadwick Jr, W W" uniqKey="Chadwick Jr W" first="W. W." last="Chadwick Jr.">W. W. Chadwick Jr.</name><name sortKey="Haxel, J H" sort="Haxel, J H" uniqKey="Haxel J" first="J. H." last="Haxel">J. H. Haxel</name><name sortKey="Matsumoto, H" sort="Matsumoto, H" uniqKey="Matsumoto H" first="H." last="Matsumoto">H. Matsumoto</name><name sortKey="Shaw, A M" sort="Shaw, A M" uniqKey="Shaw A" first="A. M." last="Shaw">A. M. Shaw</name><name sortKey="Walker, S L" sort="Walker, S L" uniqKey="Walker S" first="S. L." last="Walker">S. L. Walker</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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