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5. Seismic wave detectability on Venus using ground deformation sensors, infrasound sensors on balloons and airglow imagers

Author

Garcia, Raphael F., primary, Zelst, Iris van, additional, Kawamura, Taichi, additional, Näsholm, Sven Peter, additional, Horleston, Anna Catherine, additional, Klaasen, Sara, additional, Lefevre, Maxence, additional, Solberg, Céline Marie, additional, Smolinski, Krystyna T., additional, Plesa, Ana-Catalina, additional, Brissaud, Quentin, additional, Maia, Julia S., additional, Stähler, Simon C., additional, Lognonné, Philippe, additional, Panning, Mark Paul, additional, Gülcher, Anna, additional, Ghail, Richard, additional, and Toffoli, Barbara De, additional

Published
2024
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6. Retrieving Seismic Source Characteristics Using Seismic and Infrasound Data: The 2020 ML 4.1 Kiruna Minequake, Sweden.

Author

Turquet, Antoine, Brissaud, Quentin, Alvizuri, Celso, Näsholm, Sven Peter, Le Pichon, Alexis, and Kero, Johan

Subjects
*INFRASONIC waves, *IRON mining, *SOUND waves, *ACOUSTIC models, *ATMOSPHERIC temperature, *SEISMIC waves, *INVERSION (Geophysics)
Abstract

A minequake of magnitude ML 4.1 occurred on 18 May 2020 early in the morning at the LKAB underground iron ore mine in Kiruna, Sweden. This is the largest mining‐induced earthquake in Scandinavia. It generated acoustic signals observed at three infrasound arrays at 9.3 (KRIS, Sweden), 155 (IS37, Norway), and 286 km (ARCI, Norway) distance. We perform full‐waveform focal mechanism inversion based on regional seismic data and local infrasound data. These independently highlight that this event was dominated by a shallow‐depth collapse in agreement with in‐mine seismic station data. However, regional infrasound data cannot inform the inversion process without an accurate model of atmospheric winds and temperatures. Yet, our numerical simulations demonstrate a potential of using local and regional infrasound data to constrain an event's focal mechanism and depth. Plain Language Summary: The largest mining‐induced earthquake in Scandinavia (ML 4.1) occurred on 18 May 2020 early in the morning at the LKAB underground iron ore mine in Kiruna, Sweden. The seismic waves coupled to the atmosphere and propagated large distances as sound waves which were observed at three infrasound arrays at 9.3 (KRIS, Sweden), 155 (IS37, Norway), and 286 km (ARCI, Norway) distance. Our seismic and acoustic modeling results highlight a strong collapse event within the northern section of the mine. The modeling of acoustic and seismic waves across the Earth‐atmosphere suggests that sound wave data can help when determining the location and properties of a seismic source. Key Points: Seismic and acoustic records indicate a strong collapse at shallow depth of 1 ± 0.5 km for the 2020 Kiruna minequakeFocal mechanisms and depths of shallow seismic sources can be retrieved from local infrasound recordsInversions using regional infrasound data is possible when accurate weather models are available [ABSTRACT FROM AUTHOR]

Published
2024
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10. Using a machine learning and stochastics-founded model to provide near real-time stratospheric polar vortex diagnostics based on high-latitude infrasound data

Author

Eggen, Mari, primary, Midtfjord, Alise Danielle, additional, Vorobeva, Ekaterina, additional, Benth, Fred Espen, additional, Hupe, Patrick, additional, Brissaud, Quentin, additional, Orsolini, Yvan, additional, Le Pichon, Alexis, additional, Listowski, Constantino, additional, and Näsholm, Sven Peter, additional

Published
2023
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13. Summarizing the research of the MADEIRA project - Middle atmosphere dynamics: exploiting infrasound using a multidisciplinary approach at high latitudes

Author

Näsholm, Sven Peter, primary, Amezcua, Javier, additional, Assink, Jelle D., additional, Belova, Evgenia, additional, Blixt, Erik Mårten, additional, Brissaud, Quentin, additional, Eggen, Mari Dahl, additional, Espy, Patrick J., additional, Hibbins, Robert, additional, Kero, Johan, additional, Kvaerna, Tormod, additional, Le Pichon, Alexis, additional, Orsolini, Yvan J., additional, Vera Rodriguez, Ismael, additional, Turquet, Antoine, additional, and Vorobeva, Ekaterina, additional

Published
2023
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15. A global analysis of deep infrasound produced by the January 2022 eruption of Hunga volcano

Author

Vergoz, Julien, primary, Le Pichon, Alexis, additional, Listowski, Constantino, additional, Hupe, Patrick, additional, Pilger, Christopher, additional, Gaebler, Peter, additional, Ceranna, Lars, additional, Garcés, Milton, additional, Marchetti, Emanuele, additional, Labazuy, Philippe, additional, Mialle, Pierrick, additional, Brissaud, Quentin, additional, Näsholm, Peter, additional, Shapiro, Nikolai, additional, and Poli, Piero, additional

Published
2022
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16. Introduction to the Special Section on Seismoacoustics and Seismoacoustic Data Fusion.

Author

Dugick, Fransiska K. Dannemann, Bishop, Jordan W., Martire, Léo, Iezzi, Alexandra M., Assink, Jelle D., Brissaud, Quentin, and Arrowsmith, Stephen

Abstract

A variety of geophysical hazards (e.g., volcanic activity, earthquakes, mass movements, marine storms, and bolides) and anthropogenic sources (e.g., chemical and nuclear explosions, mining blasts, rocket launches, and military activity) can release energy as mechanical waves in the ground, ocean, and atmosphere (Campus and Christie, 2009; Arrowsmith et al., 2010). Because of the mechanical coupling between a planetary body, its ocean, and its atmosphere, waves propagate across these interfaces (Ben-Menahem and Singh, 1981) and carry information about the source and the media they propagated through. The field of seismoacoustics, driven by geophysical observations of.. [ABSTRACT FROM AUTHOR]

Published
2023
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18. Atmospheric waves and global seismoacoustic observations of the January 2022 Hunga eruption, Tonga

Author

Matoza, Robin S., primary, Fee, David, additional, Assink, Jelle D., additional, Iezzi, Alexandra M., additional, Green, David N., additional, Kim, Keehoon, additional, Toney, Liam, additional, Lecocq, Thomas, additional, Krishnamoorthy, Siddharth, additional, Lalande, Jean-Marie, additional, Nishida, Kiwamu, additional, Gee, Kent L., additional, Haney, Matthew M., additional, Ortiz, Hugo D., additional, Brissaud, Quentin, additional, Martire, Léo, additional, Rolland, Lucie, additional, Vergados, Panagiotis, additional, Nippress, Alexandra, additional, Park, Junghyun, additional, Shani-Kadmiel, Shahar, additional, Witsil, Alex, additional, Arrowsmith, Stephen, additional, Caudron, Corentin, additional, Watada, Shingo, additional, Perttu, Anna B., additional, Taisne, Benoit, additional, Mialle, Pierrick, additional, Le Pichon, Alexis, additional, Vergoz, Julien, additional, Hupe, Patrick, additional, Blom, Philip S., additional, Waxler, Roger, additional, De Angelis, Silvio, additional, Snively, Jonathan B., additional, Ringler, Adam T., additional, Anthony, Robert E., additional, Jolly, Arthur D., additional, Kilgour, Geoff, additional, Averbuch, Gil, additional, Ripepe, Maurizio, additional, Ichihara, Mie, additional, Arciniega-Ceballos, Alejandra, additional, Astafyeva, Elvira, additional, Ceranna, Lars, additional, Cevuard, Sandrine, additional, Che, Il-Young, additional, De Negri, Rodrigo, additional, Ebeling, Carl W., additional, Evers, Läslo G., additional, Franco-Marin, Luis E., additional, Gabrielson, Thomas B., additional, Hafner, Katrin, additional, Harrison, R. Giles, additional, Komjathy, Attila, additional, Lacanna, Giorgio, additional, Lyons, John, additional, Macpherson, Kenneth A., additional, Marchetti, Emanuele, additional, McKee, Kathleen F., additional, Mellors, Robert J., additional, Mendo-Pérez, Gerardo, additional, Mikesell, T. Dylan, additional, Munaibari, Edhah, additional, Oyola-Merced, Mayra, additional, Park, Iseul, additional, Pilger, Christoph, additional, Ramos, Cristina, additional, Ruiz, Mario C., additional, Sabatini, Roberto, additional, Schwaiger, Hans F., additional, Tailpied, Dorianne, additional, Talmadge, Carrick, additional, Vidot, Jérôme, additional, Webster, Jeremy, additional, and Wilson, David C., additional

Published
2022
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19. Atmospheric waves and global seismoacoustic observations of the January 2022 Hunga eruption, Tonga

Author

Matoza, Robin, Fee, David, Assink, Jelle, Iezzi, Alexandra, Green, D A, Aalders, Kim K.C., Toney, Liam, Lecocq, Thomas TL, Krishnamoorthy, Siddharth, Lalande, Jean-Marie, Nishida, Kiwamu, De Geest, Koen De K., Haney, Matthew, Ortiz, Hugo, Brissaud, Quentin, Martire, Luca, Galmiche-Rolland, Louise, Vergados, Panagiotis, Nippress, Alexandra, Landman Parker, Judith, Shani-Kadmiel, Shahar, Witsil, Alex, Arrowsmith, Stephen, Caudron, Corentin, Watada, Shingo, Perttu, Anna, Taisne, Benoit, Mialle, Pierrick, Le Pichon, Alexis, Vergoz, Julien, Hupe, Patrick, Blom, Philip S., Waxler, Roger, De Angelis, Silvio, Snively, Jonathan, Ringler, Adam, Anthony, Robert E., Jolly, Antoine, Kilgour, Geoff, Averbuch, Gil, Ripepe, Maurizio, Ichihara, Mie, Arciniega-Ceballos, Alejandra, Astafyeva, Elvira, Ceranna, Lars, Cevuard, Sandrine, Che, Il-Young, De Negri, Rodrigo, Ebeling, Carl, Evers, Luc, Franco-Marin, Luis, Gabrielson, Thomas, Hafner, Katrin, Harrison, R. Giles, Komjathy, Attila, Lacanna, Giorgio, Lyons, John, Macpherson, Kenneth, Marchetti, Emanuele, Mckee, Karen, Mellors, Robert, Mendo-Pérez, Gerardo, Mikesell, Dylan, Munaibari, Edhah, Oyola-Merced, Mayra, Park, Iseul, Pilger, C, Ramos, Cristina, Aroca Ruiz, María, Sabatini, Roberto, Schwaiger, Hannes, Tailpied, Dorianne, Talmadge, Carrick, Vidot, Jérôme, Webster, J, Wilson, D, Matoza, Robin, Fee, David, Assink, Jelle, Iezzi, Alexandra, Green, D A, Aalders, Kim K.C., Toney, Liam, Lecocq, Thomas TL, Krishnamoorthy, Siddharth, Lalande, Jean-Marie, Nishida, Kiwamu, De Geest, Koen De K., Haney, Matthew, Ortiz, Hugo, Brissaud, Quentin, Martire, Luca, Galmiche-Rolland, Louise, Vergados, Panagiotis, Nippress, Alexandra, Landman Parker, Judith, Shani-Kadmiel, Shahar, Witsil, Alex, Arrowsmith, Stephen, Caudron, Corentin, Watada, Shingo, Perttu, Anna, Taisne, Benoit, Mialle, Pierrick, Le Pichon, Alexis, Vergoz, Julien, Hupe, Patrick, Blom, Philip S., Waxler, Roger, De Angelis, Silvio, Snively, Jonathan, Ringler, Adam, Anthony, Robert E., Jolly, Antoine, Kilgour, Geoff, Averbuch, Gil, Ripepe, Maurizio, Ichihara, Mie, Arciniega-Ceballos, Alejandra, Astafyeva, Elvira, Ceranna, Lars, Cevuard, Sandrine, Che, Il-Young, De Negri, Rodrigo, Ebeling, Carl, Evers, Luc, Franco-Marin, Luis, Gabrielson, Thomas, Hafner, Katrin, Harrison, R. Giles, Komjathy, Attila, Lacanna, Giorgio, Lyons, John, Macpherson, Kenneth, Marchetti, Emanuele, Mckee, Karen, Mellors, Robert, Mendo-Pérez, Gerardo, Mikesell, Dylan, Munaibari, Edhah, Oyola-Merced, Mayra, Park, Iseul, Pilger, C, Ramos, Cristina, Aroca Ruiz, María, Sabatini, Roberto, Schwaiger, Hannes, Tailpied, Dorianne, Talmadge, Carrick, Vidot, Jérôme, Webster, J, and Wilson, D

Abstract

The 15 January 2022 climactic eruption of Hunga volcano, Tonga, produced an explosion in the atmosphere of a size that has not been documented in the modern geophysical record. The event generated a broad range of atmospheric waves observed globally by various ground-based and spaceborne instrumentation networks. Most prominent is the surface-guided Lamb wave ( ≲ 0.01 Hz), which we observed propagating for four (+three antipodal) passages around the Earth over six days. Based on Lamb wave amplitudes, the climactic Hunga explosion was comparable in size to that of the 1883 Krakatau eruption. The Hunga eruption produced remarkable globally-detected infrasound (0.01–20 Hz), long-range (~10,000 km) audible sound, and ionospheric perturbations. Seismometers worldwide recorded pure seismic and air-to-ground coupled waves. Air-to-sea coupling likely contributed to fast-arriving tsunamis. We highlight exceptional observations of the atmospheric waves., SCOPUS: ar.j, info:eu-repo/semantics/published

Published
2022

26. Predicting infrasound transmission loss using deep learning.

Author

Brissaud, Quentin, Näsholm, Sven Peter, Turquet, Antoine, and Le Pichon, Alexis

Subjects
*INFRASONIC waves, *DEEP learning, *ATMOSPHERIC models, *ARTIFICIAL intelligence
Abstract

Modelling the spatial distribution of infrasound attenuation (or transmission loss, TL) is key to understanding and interpreting microbarometer data and observations. Such predictions enable the reliable assessment of infrasound source characteristics such as ground pressure levels associated with earthquakes, man-made or volcanic explosion properties, and ocean-generated microbarom wavefields. However, the computational cost inherent in full-waveform modelling tools, such as parabolic equation (PE) codes, often prevents the exploration of a large parameter space, that is variations in wind models, source frequency and source location, when deriving reliable estimates of source or atmospheric properties—in particular for real-time and near-real-time applications. Therefore, many studies rely on analytical regression-based heuristic TL equations that neglect complex vertical wind variations and the range-dependent variation in the atmospheric properties. This introduces significant uncertainties in the predicted TL. In the current contribution, we propose a deep learning approach trained on a large set of simulated wavefields generated using PE simulations and realistic atmospheric winds to predict infrasound ground-level amplitudes up to 1000 km from a ground-based source. Realistic range dependent atmospheric winds are constructed by combining ERA5, NRLMSISE-00 and HWM-14 atmospheric models, and small-scale gravity-wave perturbations computed using the Gardner model. Given a set of wind profiles as input, our new modelling framework provides a fast (0.05 s runtime) and reliable (∼5 dB error on average, compared to PE simulations) estimate of the infrasound TL. [ABSTRACT FROM AUTHOR]

Published
2023
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29. What can the sound of earthquakes tell us about a planet’s interior structure?

Author

Brissaud, Quentin, Krishnamoorthy, Siddharth, Jackson, Jennifer M., Bowman, Daniel C., Komjathy, Attila, Cutts, James, Zhan, Zhongwen, Pauken, Michael T., Izraelevitz, Jacob S., Walsh, Gerald J., Brissaud, Quentin, Krishnamoorthy, Siddharth, Jackson, Jennifer M., Bowman, Daniel C., Komjathy, Attila, Cutts, James, Zhan, Zhongwen, Pauken, Michael T., Izraelevitz, Jacob S., and Walsh, Gerald J.

Abstract

Deploying seismic or infrasound arrays on the ground to probe a planet’s interior structure remains challenging in remote regions facing harsh surface conditions such as Venus with a surface temperature of 464°C. Fortunately, a fraction of the seismic energy transmits in the upper atmosphere as infrasound waves, i.e. low-frequency pressure perturbations (< 20Hz). On July 22, 2019, a heliotrope balloon, equipped with pressure sensors, was launched from the Johnson Valley, CA with the objective of capturing infrasound signals from the aftershock sequence of the 2019 Ridgecrest earthquake. At 16:27:36 UTC, the sound of a natural earthquake of Mw 4.2 was detected for the first time by a balloon platform. This observation offered the opportunity to attempt the first inversion of seismic velocities from the atmosphere. Shear velocities extracted by our analytical inversion method fell within a reasonable range from the values provided by regional tomographic models. While our analysis was limited by the observation’s low signal-to-noise ratio, future observations of seismic events from a network of balloons carrying multiple pressure sensors could provide excellent constraints on crustal properties. However, to build robust estimates of seismic properties, inversion procedures will have to account for uncertainties in terms of velocity models, source locations, and instrumental errors. In this contribution, we will discuss the current state of balloon-based observations, the sensitivity of the acoustic wavefield on subsurface properties, and perspectives on future inversions of seismically-induced acoustic data.

Published
2021

34. Retrieving Seismic Source Characteristics Using Seismic and Infrasound Data: The 2020 ML4.1 Kiruna Minequake, Sweden

Author

Turquet, Antoine, Brissaud, Quentin, Alvizuri, Celso, Näsholm, Sven Peter, Le Pichon, Alexis, and Kero, Johan

Abstract

A minequake of magnitude ML4.1 occurred on 18 May 2020 early in the morning at the LKAB underground iron ore mine in Kiruna, Sweden. This is the largest mining‐induced earthquake in Scandinavia. It generated acoustic signals observed at three infrasound arrays at 9.3 (KRIS, Sweden), 155 (IS37, Norway), and 286 km (ARCI, Norway) distance. We perform full‐waveform focal mechanism inversion based on regional seismic data and local infrasound data. These independently highlight that this event was dominated by a shallow‐depth collapse in agreement with in‐mine seismic station data. However, regional infrasound data cannot inform the inversion process without an accurate model of atmospheric winds and temperatures. Yet, our numerical simulations demonstrate a potential of using local and regional infrasound data to constrain an event's focal mechanism and depth. The largest mining‐induced earthquake in Scandinavia (ML4.1) occurred on 18 May 2020 early in the morning at the LKAB underground iron ore mine in Kiruna, Sweden. The seismic waves coupled to the atmosphere and propagated large distances as sound waves which were observed at three infrasound arrays at 9.3 (KRIS, Sweden), 155 (IS37, Norway), and 286 km (ARCI, Norway) distance. Our seismic and acoustic modeling results highlight a strong collapse event within the northern section of the mine. The modeling of acoustic and seismic waves across the Earth‐atmosphere suggests that sound wave data can help when determining the location and properties of a seismic source. Seismic and acoustic records indicate a strong collapse at shallow depth of 1  ±  0.5 km for the 2020 Kiruna minequakeFocal mechanisms and depths of shallow seismic sources can be retrieved from local infrasound recordsInversions using regional infrasound data is possible when accurate weather models are available Seismic and acoustic records indicate a strong collapse at shallow depth of 1  ±  0.5 km for the 2020 Kiruna minequake Focal mechanisms and depths of shallow seismic sources can be retrieved from local infrasound records Inversions using regional infrasound data is possible when accurate weather models are available

Published
2024
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35. Numerical modeling of atmospheric waves due to Earth/Ocean/Atmosphere couplings and applications

Author

Brissaud, Quentin, Brissaud, Quentin, California Institute of Technology (CALTECH), ISAE, and Raphael Garcia

Subjects
Finite differences, Atmosphères planétaires, [SDU.STU.PL]Sciences of the Universe [physics]/Earth Sciences/Planetology, Couplage Terre-atmosphère, Discontinuous Galerkin method, Tsunamis, Ondes atmosphériques, Earth-atmosphere coupling, Différences finies, [SDU.STU.PL] Sciences of the Universe [physics]/Earth Sciences/Planetology, Méthode de Galerkin discontinue, Atmospheric wave, Planetary atmospheres
Abstract

This thesis deals with the wave propagation problem within the Earth-oceanatmospherecoupled system. A good understanding of the these phenomena has a majorimportance for seismic and atmospheric explosion studies, especially for planetary missions.Atmospheric wave-forms generated by explosions or surface oscillations can bring valuableinformation about the source mechanism or the properties of the various propagation media.We develop two new numerical full-wave high-order modeling tools to model the propagationof acoustic and gravity waves in realistic atmospheres. The first one relies on a high-order staggeredfinite difference method and focus only on the atmosphere. It enables the simultaneouspropagation of linear acoustic and gravity waves in stratified viscous and windy atmosphere.This method is validated against quasi-analytical solutions based on the dispersion equationsfor a stratified atmosphere. It has also been employed to investigate two cases : the atmosphericpropagation generated by a meteor impact on Mars for the INSIGHT NASA missionand for the study of tsunami-induced acoutic and gravity waves following the 2004 Sumatratsunami. The second numerical method resolves the non-linear acoustic and gravity wavepropagation in a realistic atmosphere coupled, with topography, to the elastic wave propagationin a visco-elastic solid. This numerical tool relies on a discontinuous Galerkin method tosolve the full Navier-Stokes equations in the fluid domain and a continuous Galerkin methodto solve the elastodynamics equations in the solid domain. It is validated against analyticalsolutions and numerical results provided by the finite-difference method. This method couldbe employed for numerous applications cases such as near-surface Earthquakes, atmosphericexplosions from bolide airburst or to investigate non-linear acoustic and gravity wavepropagation in a realistic atmosphere., Cette thèse se penche sur la propagation d’ondes au sein du système coupléTerre-océan-atmosphère. La compréhension de ces phénomènes a une importance majeurepour l’étude de perturbations sismiques et d’explosions atmosphériques notamment dans lecadre de missions spatiales planétaires. Les formes d’ondes atmosphériques issues du couplagefluide-solide permettent d’obtenir de précieuses informations sur la source du signal ou lespropriétés des milieux de propagation. On développe donc deux outils de modélisation numériqued’ordre élevé pour la propagation d’ondes acoustiques et de gravité. Le premier est endifférences finies sur grille en quinconce et se concentre uniquement sur le milieu atmosphérique,permettant la propagation d’ondes linéaires dans un milieu stratifié visqueux et avecdu vent. Cette méthode linéaire est validée par des solutions quasi-analytiques reposant surles équations de dispersion dans une atmosphère stratifiée. Elle est aussi appliquée à deuxcas d’études : la propagation d’ondes liée à l’impact d’une météorite à la surface de Marsdans le cadre de la mission de la NASA INSIGHT, et la propagation d’ondes atmosphériquesliées au tsunami de Sumatra en 2004. La seconde méthode résout la propagation non-linéaired’ondes acoustiques et de gravité dans une atmosphère complexe couplée, avec topographie,à la propagation d’ondes élastiques dans un solide visco-élastique. Cette méthode repose sursur le couplage d’une formulation en éléments finis discontinus, pour résoudre les équationsde Navier-Stokes dans la partie fluide, avec une méthode par éléments finis continus pourrésoudre les équations de l’élastodynamique dans la partie solide. Elle a été validée grâce àdes solutions analytiques ainsi que par des comparaisons avec les résultats de la méthode pardifférences finies. De nombreuses applications de cette méthode sont alors possibles notammentpour l’étude de séismes de sub-surface, d’explosions atmosphériques liées à la rentréede météorites ou pour la caractérisation des phénomènes non-linéaires lors de la propagationd’infrasons et d’ondes de gravité dans l’atmosphère.

Published
2017

38. Modélisation numérique des ondes atmosphériques issues des couplages solide/océan/atmosphère et applications

Author

Brissaud, Quentin, California Institute of Technology (CALTECH), ISAE, Raphael Garcia, Institut Supérieur de l'Aéronautique et de l'Espace, Garcia, Raphaël, and Martin, Roland

Subjects
Finite differences, 621.382 2, Méthode de Galerkin discontinue, Atmosphères planétaires, Couplage Terre-atmosphère, [SDU.STU.PL]Sciences of the Universe [physics]/Earth Sciences/Planetology, Discontinuous Galerkin method, Tsunamis, Ondes atmosphériques, Earth-atmosphere coupling, Différences finies, Atmospheric wave, Planetary atmospheres
Abstract

This thesis deals with the wave propagation problem within the Earth-oceanatmospherecoupled system. A good understanding of the these phenomena has a majorimportance for seismic and atmospheric explosion studies, especially for planetary missions.Atmospheric wave-forms generated by explosions or surface oscillations can bring valuableinformation about the source mechanism or the properties of the various propagation media.We develop two new numerical full-wave high-order modeling tools to model the propagationof acoustic and gravity waves in realistic atmospheres. The first one relies on a high-order staggeredfinite difference method and focus only on the atmosphere. It enables the simultaneouspropagation of linear acoustic and gravity waves in stratified viscous and windy atmosphere.This method is validated against quasi-analytical solutions based on the dispersion equationsfor a stratified atmosphere. It has also been employed to investigate two cases : the atmosphericpropagation generated by a meteor impact on Mars for the INSIGHT NASA missionand for the study of tsunami-induced acoutic and gravity waves following the 2004 Sumatratsunami. The second numerical method resolves the non-linear acoustic and gravity wavepropagation in a realistic atmosphere coupled, with topography, to the elastic wave propagationin a visco-elastic solid. This numerical tool relies on a discontinuous Galerkin method tosolve the full Navier-Stokes equations in the fluid domain and a continuous Galerkin methodto solve the elastodynamics equations in the solid domain. It is validated against analyticalsolutions and numerical results provided by the finite-difference method. This method couldbe employed for numerous applications cases such as near-surface Earthquakes, atmosphericexplosions from bolide airburst or to investigate non-linear acoustic and gravity wavepropagation in a realistic atmosphere.; Cette thèse se penche sur la propagation d’ondes au sein du système coupléTerre-océan-atmosphère. La compréhension de ces phénomènes a une importance majeurepour l’étude de perturbations sismiques et d’explosions atmosphériques notamment dans lecadre de missions spatiales planétaires. Les formes d’ondes atmosphériques issues du couplagefluide-solide permettent d’obtenir de précieuses informations sur la source du signal ou lespropriétés des milieux de propagation. On développe donc deux outils de modélisation numériqued’ordre élevé pour la propagation d’ondes acoustiques et de gravité. Le premier est endifférences finies sur grille en quinconce et se concentre uniquement sur le milieu atmosphérique,permettant la propagation d’ondes linéaires dans un milieu stratifié visqueux et avecdu vent. Cette méthode linéaire est validée par des solutions quasi-analytiques reposant surles équations de dispersion dans une atmosphère stratifiée. Elle est aussi appliquée à deuxcas d’études : la propagation d’ondes liée à l’impact d’une météorite à la surface de Marsdans le cadre de la mission de la NASA INSIGHT, et la propagation d’ondes atmosphériquesliées au tsunami de Sumatra en 2004. La seconde méthode résout la propagation non-linéaired’ondes acoustiques et de gravité dans une atmosphère complexe couplée, avec topographie,à la propagation d’ondes élastiques dans un solide visco-élastique. Cette méthode repose sursur le couplage d’une formulation en éléments finis discontinus, pour résoudre les équationsde Navier-Stokes dans la partie fluide, avec une méthode par éléments finis continus pourrésoudre les équations de l’élastodynamique dans la partie solide. Elle a été validée grâce àdes solutions analytiques ainsi que par des comparaisons avec les résultats de la méthode pardifférences finies. De nombreuses applications de cette méthode sont alors possibles notammentpour l’étude de séismes de sub-surface, d’explosions atmosphériques liées à la rentréede météorites ou pour la caractérisation des phénomènes non-linéaires lors de la propagationd’infrasons et d’ondes de gravité dans l’atmosphère.

Published
2017

39. Numerical Simulation of the Atmospheric Signature of Artificial and Natural Seismic Events

Author

Martire, Léo, primary, Brissaud, Quentin, additional, Lai, Voon Hui, additional, Garcia, Raphaël F., additional, Martin, Roland, additional, Krishnamoorthy, Siddharth, additional, Komjathy, Attila, additional, Cadu, Alexandre, additional, Cutts, James A., additional, Jackson, Jennifer M., additional, Mimoun, David, additional, Pauken, Michael T., additional, and Sournac, Anthony, additional

Published
2018
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40. Atmospheric Science with InSight

Author

Spiga, Aymeric, primary, Banfield, Don, additional, Teanby, Nicholas A., additional, Forget, François, additional, Lucas, Antoine, additional, Kenda, Balthasar, additional, Rodriguez Manfredi, Jose Antonio, additional, Widmer-Schnidrig, Rudolf, additional, Murdoch, Naomi, additional, Lemmon, Mark T., additional, Garcia, Raphaël F., additional, Martire, Léo, additional, Karatekin, Özgür, additional, Le Maistre, Sébastien, additional, Van Hove, Bart, additional, Dehant, Véronique, additional, Lognonné, Philippe, additional, Mueller, Nils, additional, Lorenz, Ralph, additional, Mimoun, David, additional, Rodriguez, Sébastien, additional, Beucler, Éric, additional, Daubar, Ingrid, additional, Golombek, Matthew P., additional, Bertrand, Tanguy, additional, Nishikawa, Yasuhiro, additional, Millour, Ehouarn, additional, Rolland, Lucie, additional, Brissaud, Quentin, additional, Kawamura, Taichi, additional, Mocquet, Antoine, additional, Martin, Roland, additional, Clinton, John, additional, Stutzmann, Éléonore, additional, Spohn, Tilman, additional, Smrekar, Suzanne, additional, and Banerdt, William B., additional

Published
2018
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43. Probing the Interior Structure of Venus

Author

Stevenson, David J., Cutts, James A., Mimoun, David, Arrowsmith, Stephen, Banerdt, W. Bruce, Blom, Philip, Brageot, Emily, Brissaud, Quentin, Chin, Gordon, Gao, Peter, Garcia, Raphael, Hall, Jeffrey L., Hunter, Gary, Jackson, Jennifer M., Kerzhanovich, V. V., Kiefer, Walter, Komjathy, Attila, Lee, Christopher, Lognonné, P., Lorenz, Ralph, Majid, W., Mojarradi, Mohammed, Nolet, Guust, O'Rourke, Joseph G., Rolland, Lucie, Shubert, Gerald, Simons, Mark, Sotin, Christophe, Spilker, Tom, and Tsai, Victor C.

Abstract

The formation, evolution, and structure of Venus remain a mystery more than 50 years after the first visit by a robotic spacecraft. Radar images have revealed a surface that is much younger than those of the Moon, Mercury, and Mars as well as a variety of enigmatic volcanic and tectonic features quite unlike those we are familiar with on Earth. What are the dynamic processes that shape these features, in the absence of any plate tectonics? What is their relationship with the dense Venus atmosphere, which envelops Venus like an ocean? To understand how Venus works as a planet, we now need to probe its interior. Conventional seismology for probing the interior of a planet employs extremely sensitive motion or speed detectors in contact with the planetary surface. For Venus, these sensors must be deployed on the surface and must tolerate the Venus environment (460 degrees C and 90 bars) for up to a year. The dense atmosphere of Venus, which efficiently couples seismic energy into the atmosphere as infrasonic waves, enables two alternatives: detection of these infrasonic waves in the middle atmosphere using a string of two or more microbarometers suspended from a floating platform or detection with an orbiting spacecraft of electromagnetic signatures produced by interactions of infrasonic waves in the Venus upper atmosphere and ionosphere. This report, describing the findings of a workshop, sponsored by the Keck Institute of Space Studies (KISS), concludes that seismic investigations can be successful conducted from all three vantage points—surface, middle atmosphere, and space. Separately or, better still, together, these measurements from these vantage points can be used to transform knowledge of Venus seismicity and the interior structure of Venus. Under the auspices of KISS, a multidisciplinary study team was formed to explore the feasibility of investigating the interior of the planet with seismological techniques. Most of the team’s work was conducted in a five-day workshop held at the KISS facility at the California Institute of Technology (Caltech) campus from June 2–6, 2014. This report contains the key findings of that workshop and recommendations for future work. Seismicity of Venus: The study team first performed an assessment of the seismicity of Venus and the likelihood that the planet experiences active seismic activity. The morphology of the structural features as well as the youthfulness of the planet surface testifies to the potential for seismic activity. There is plenty of evidence that the crust of Venus has experienced stress since the relief of stress is expressed in a wide range of structural features. However, the contemporary rate of stress release is unknown and it is possible that, as on Earth, much of that stress release is aseismic. Two competing conditions on Venus will influence the likelihood of stress release. On the one hand, the lack of water would result in a larger fraction of seismic energy release; on the other hand, the higher temperatures would limit the magnitude of stress release events. Experimental measurements on candidate Venus crustal and mantle materials may help define which effect is more important. Other Sources of Seismic Energy: Volcanic events are also a potential source of seismic waves on Venus. Unlike Mars, where volcanic activity appears to have ended, infrared orbital measurements may indicate that some volcanoes on Venus are still active. Disturbances due to large bolides impacting the atmosphere may also be recorded but are unlikely to be useful for probing the planetary interior. More useful than these point sources of energy will be energy injected into the subsurface from the dynamic atmosphere by atmosphere-surface coupling. This distributed source may be useful for probing the subsurface using the methods of ambient noise tomography. Atmospheric Propagation: Acoustic waves from a seismic event are coupled much more efficiently into the atmosphere than on Earth. The coupling efficiency is intermediate between that for the Earth’s atmosphere and the ocean. Signals propagating from directly above the epicenter or from a surface wave propagating out from the quake epicenter both travel up into the atmosphere. Because the atmosphere is primarily carbon dioxide, attenuation is higher than it would be in an atmosphere with non-polar molecules. The attenuation is frequency dependent and only impacts frequencies well above 10 Hz at the altitude of a floating platform (54 km). For observations from a space platform, it may be important at much lower frequencies to 1 mHz. Detection from a Floating Platform: Infrasonic pressure signals emanating either directly above the epicenter of a seismic event or from the (surface) Rayleigh wave can be picked up by microbarometers deployed from a balloon floating in the favorable environment of the middle atmosphere of Venus atmosphere. Two or more microbarometers deployed on a tether beneath the balloon will be needed to discriminate pressure variations caused by an upwardly propagating surface wave resulting from the effects of altitude changes (updrafts and downdrafts) and changes in buoyancy of the balloon. The platform will circumnavigate Venus every few days enabling a survey of Venus seismicity. Orbital Detection: Observations from a spacecraft in orbit around Venus enable a broad range of techniques for investigating the perturbations of the neutral atmosphere and ionosphere by seismic waves. Our initial analyses confirm that non-local thermodynamic equilibrium CO_2 emissions on the day side (at 4.3 µm) will present variations induced by adiabatic pressure and density variations and energy deposition created by both acoustic and gravity waves. For detection purposes, the advantage of this emission compared to other ones considered during the study (O_2 night side airglow at 1.27 µm or ultraviolet [UV] day side emission at 220 nm) is a smoothly varying background with solar zenith angle, because of a strong CO_2 absorption at this wavelength below 110 km. Surface Detection: While important seismic measurements can be made from both balloon altitudes and from orbit, the measurement of all three dimensions of the ground motion can only be made by a sensor on the surface of Venus. However, at present, the technology for seismic experiments on the surface of Venus does not exist. Development of a seismic measurement capability equivalent to the Seismic and Interior Structure (SEIS) for the Mars InSight (Interior Exploration using Seismic Investigations, Geodesy and Heat Transport) spacecraft is many years if not decades away. However, useful measurements of the ambient noise on the surface of Venus are feasible with existing technology and would be vital for both the design of a future seismic station with high sensitivity for teleseismic events and a pair or network of stations that could probe the interior using ambient noise tomography. Synergistic Observations in All Three Modes: The synoptic orbital view for a remote sensing spacecraft in a high orbit would enable not only sensitive detection and localization of Venus quakes with excellent background discrimination but potentially precise measurements of the propagation of the seismic surface wave counterpart in the higher atmosphere. Complementary observations of the same event at the much higher frequencies that are possible from in situ platforms on the surface and in the middle atmosphere would greatly enhance the ability to survey seismicity and probe the Venus interior. The Path Forward: The first step going forward is to develop the detailed requirements of the proposed payloads and to carry out related technology developments and laboratory or field demonstrations. In undertaking this process, we need to know more about the properties of potential Venus crustal and mantle rocks through laboratory studies and the potential of ambient noise tomography at Venus through analysis. Once this is done, our strategy for investigating the internal structure of Venus is built around programmatic realities—the missions that NASA, European Space Agency (ESA), Japan Aerospace Exploration Agency (JAXA), and the Russian Federal Space Agency (RFSA) are currently flying, are under development, or are being planned. A primary goal should be technology demonstration experiments on Venus missions where seismology is not currently an objective. These include infrasonic background measurements from a Venus balloon and infrared and visible signatures from an orbiter that might be implemented under NASA’s Discovery program or as an ESA M-series mission. It would also include seismic background signals and a potential active seismic experiment from a short duration lander such as NASA’s proposed New Frontiers Venus In Situ Explorer (VISE) mission. This would be followed with a much more capable mission equipped to investigate seismicity and interior structure. The orbital and balloon platforms needed for such a mission are also features of the Venus Climate Mission (VCM), a Flagship mission endorsed by the Planetary Science Decadal Survey in 2011. The study team recommends study of a Venus Climate and Interior Mission (VCIM), which could benefit from commonalities in spacecraft systems, and secure the support of the broad planetary science community for its Flagship mission for the next decade.

Published
2015
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45. Finite-Difference Modeling of Acoustic and Gravity Wave Propagation in Mars Atmosphere: Application to Infrasounds Emitted by Meteor Impacts.

Author

Garcia, Raphael, Brissaud, Quentin, Rolland, Lucie, Martin, Roland, Komatitsch, Dimitri, Spiga, Aymeric, Lognonné, Philippe, and Banerdt, Bruce

Subjects
*THEORY of wave motion, *ACOUSTIC wave propagation, *GRAVITATIONAL waves, *MARTIAN atmosphere, *METEORS, *FINITE difference method
Abstract

The propagation of acoustic and gravity waves in planetary atmospheres is strongly dependent on both wind conditions and attenuation properties. This study presents a finite-difference modeling tool tailored for acoustic-gravity wave applications that takes into account the effect of background winds, attenuation phenomena (including relaxation effects specific to carbon dioxide atmospheres) and wave amplification by exponential density decrease with height. The simulation tool is implemented in 2D Cartesian coordinates and first validated by comparison with analytical solutions for benchmark problems. It is then applied to surface explosions simulating meteor impacts on Mars in various Martian atmospheric conditions inferred from global climate models. The acoustic wave travel times are validated by comparison with 2D ray tracing in a windy atmosphere. Our simulations predict that acoustic waves generated by impacts can refract back to the surface on wind ducts at high altitude. In addition, due to the strong nighttime near-surface temperature gradient on Mars, the acoustic waves are trapped in a waveguide close to the surface, which allows a night-side detection of impacts at large distances in Mars plains. Such theoretical predictions are directly applicable to future measurements by the INSIGHT NASA Discovery mission. [ABSTRACT FROM AUTHOR]

Published
2017
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