Aerial seismology using balloon-based barometers

Siddharth Krishnamoorthy; Ervan Kassarian; Leo Martire; Anthony Sournac; Alexandre Cadu; Voon Hui Lai; Attila Komjathy; Michael T. Pauken; James A. Cutts; Raphael F. Garcia; David Mimoun; Jennifer M. Jackson; Daniel C. Bowman

doi:10.1109/TGRS.2019.2931831

Aerial seismology using balloon-based barometers

Siddharth Krishnamoorthy^*, Ervan Kassarian, Leo Martire, Anthony Sournac, Alexandre Cadu, Voon Hui Lai, Attila Komjathy, Michael T. Pauken, James A. Cutts, Raphael F. Garcia, David Mimoun, Jennifer M. Jackson, Daniel C. Bowman

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

26 Citations (Scopus)

Abstract

Seismology on Venus has long eluded planetary scientists due to extreme temperature and pressure conditions on its surface, which most electronics cannot withstand for mission durations required for ground-based seismic studies. We show that infrasonic (low-frequency) pressure fluctuations, generated as a result of ground motion, produced by an artificial seismic source known as a seismic hammer, and recorded using sensitive microbarometers deployed on a tethered balloon, are able to replicate the frequency content of ground motion. We also show that weak, artificial seismic activity thus produced may be geolocated by using multiple airborne barometers. The success of this technique paves the way for balloon-based aero-seismology, leading to a potentially revolutionary method to perform seismic studies from a remote airborne station on the earth and solar system objects with substantial atmospheres such as Venus and Titan.

Original language	English
Article number	8809415
Pages (from-to)	10191-10201
Number of pages	11
Journal	IEEE Transactions on Geoscience and Remote Sensing
Volume	57
Issue number	12
DOIs	https://doi.org/10.1109/TGRS.2019.2931831
Publication status	Published - Dec 2019
Externally published	Yes

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Krishnamoorthy, S., Kassarian, E., Martire, L., Sournac, A., Cadu, A., Lai, V. H., Komjathy, A., Pauken, M. T., Cutts, J. A., Garcia, R. F., Mimoun, D., Jackson, J. M., & Bowman, D. C. (2019). Aerial seismology using balloon-based barometers. IEEE Transactions on Geoscience and Remote Sensing, 57(12), 10191-10201. Article 8809415. https://doi.org/10.1109/TGRS.2019.2931831

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title = "Aerial seismology using balloon-based barometers",

abstract = "Seismology on Venus has long eluded planetary scientists due to extreme temperature and pressure conditions on its surface, which most electronics cannot withstand for mission durations required for ground-based seismic studies. We show that infrasonic (low-frequency) pressure fluctuations, generated as a result of ground motion, produced by an artificial seismic source known as a seismic hammer, and recorded using sensitive microbarometers deployed on a tethered balloon, are able to replicate the frequency content of ground motion. We also show that weak, artificial seismic activity thus produced may be geolocated by using multiple airborne barometers. The success of this technique paves the way for balloon-based aero-seismology, leading to a potentially revolutionary method to perform seismic studies from a remote airborne station on the earth and solar system objects with substantial atmospheres such as Venus and Titan.",

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author = "Siddharth Krishnamoorthy and Ervan Kassarian and Leo Martire and Anthony Sournac and Alexandre Cadu and Lai, {Voon Hui} and Attila Komjathy and Pauken, {Michael T.} and Cutts, {James A.} and Garcia, {Raphael F.} and David Mimoun and Jackson, {Jennifer M.} and Bowman, {Daniel C.}",

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AU - Martire, Leo

AU - Sournac, Anthony

AU - Cadu, Alexandre

AU - Lai, Voon Hui

AU - Komjathy, Attila

AU - Pauken, Michael T.

AU - Cutts, James A.

AU - Garcia, Raphael F.

AU - Mimoun, David

AU - Jackson, Jennifer M.

AU - Bowman, Daniel C.

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AB - Seismology on Venus has long eluded planetary scientists due to extreme temperature and pressure conditions on its surface, which most electronics cannot withstand for mission durations required for ground-based seismic studies. We show that infrasonic (low-frequency) pressure fluctuations, generated as a result of ground motion, produced by an artificial seismic source known as a seismic hammer, and recorded using sensitive microbarometers deployed on a tethered balloon, are able to replicate the frequency content of ground motion. We also show that weak, artificial seismic activity thus produced may be geolocated by using multiple airborne barometers. The success of this technique paves the way for balloon-based aero-seismology, leading to a potentially revolutionary method to perform seismic studies from a remote airborne station on the earth and solar system objects with substantial atmospheres such as Venus and Titan.

KW - Balloons

KW - infrasound

KW - remote sensing

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JO - IEEE Transactions on Geoscience and Remote Sensing

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ER -

Aerial seismology using balloon-based barometers

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