Seismic Wave Detectability on Venus Using Ground Deformation Sensors, Infrasound Sensors on Balloons and Airglow Imagers

IF 2.9 3区 地球科学 Q2 ASTRONOMY & ASTROPHYSICS Earth and Space Science Pub Date : 2024-11-06 DOI:10.1029/2024EA003670
Raphael F. Garcia, Iris van Zelst, Taichi Kawamura, Sven Peter Näsholm, Anna Horleston, Sara Klaasen, Maxence Lefèvre, Celine Marie Solberg, Krystyna T. Smolinski, Ana-Catalina Plesa, Quentin Brissaud, Julia S. Maia, Simon C. Stähler, Philippe Lognonné, Mark P. Panning, Anna Gülcher, Richard Ghail, Barbara De Toffoli
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Abstract

The relatively unconstrained internal structure of Venus is a missing piece in our understanding of the formation and evolution of the Solar System. Detection of seismic waves generated by venusquakes is crucial to determine the seismic structure of Venus' interior, as recently shown by the new seismic and geodetic constraints on Mars' interior obtained by the InSight mission. In the next decade multiple missions will fly to Venus to explore its tectonic and volcanic activity, but they will not be able to conclusively detect seismic waves, despite their potential to detect fault movements. Looking toward the next fleet of Venus missions after the ones already decided, various concepts to measure seismic waves have been proposed. These detection methods include typical geophysical ground sensors already deployed on Earth, the Moon, and Mars; pressure sensors on balloons; and imagers of high altitude emissions (airglow) on orbiters. The latter two methods target the detection of the infrasound signals generated by seismic waves and amplified during their upward propagation. Here, we provide a first comparison between the detection capabilities of these different measurement techniques and recent estimates of Venus' seismic activity. In addition, we discuss the performance requirements and measurement durations required to detect seismic waves with the various detection methods. Our study clearly presents the advantages and limitations of the different seismic wave detection techniques and can be used to drive the design of future mission concepts aiming to study the seismicity of Venus.

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利用地面形变传感器、气球上的次声传感器和气辉成像仪探测金星上的地震波
金星的内部结构相对不受约束,是我们了解太阳系形成和演化的一个缺失部分。探测金星地震产生的地震波对于确定金星内部的地震结构至关重要,正如最近 "洞察"(InSight)任务对火星内部获得的新的地震和大地测量约束所显示的那样。在未来十年中,将有多个任务飞往金星探索其构造和火山活动,但它们将无法最终探测到地震波,尽管地震波具有探测断层运动的潜力。在已经决定的下一次金星飞行任务之后,人们提出了各种测量地震波的概念。这些探测方法包括已经部署在地球、月球和火星上的典型地球物理地面传感器;气球上的压力传感器;以及轨道飞行器上的高空辐射(气辉)成像仪。后两种方法的目标是探测由地震波产生并在向上传播过程中被放大的次声信号。在此,我们首次比较了这些不同测量技术的探测能力和最近对金星地震活动的估计。此外,我们还讨论了使用各种探测方法探测地震波所需的性能要求和测量持续时间。我们的研究清楚地展示了不同地震波探测技术的优势和局限性,可用于推动旨在研究金星地震的未来任务概念的设计。
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来源期刊
Earth and Space Science
Earth and Space Science Earth and Planetary Sciences-General Earth and Planetary Sciences
CiteScore
5.50
自引率
3.20%
发文量
285
审稿时长
19 weeks
期刊介绍: Marking AGU’s second new open access journal in the last 12 months, Earth and Space Science is the only journal that reflects the expansive range of science represented by AGU’s 62,000 members, including all of the Earth, planetary, and space sciences, and related fields in environmental science, geoengineering, space engineering, and biogeochemistry.
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