Enhanced Seismic Backscattering for Lava Tube Detection

Jingchuan Wang; Nicholas C. Schmerr; Naoma McCall; Sarah Kruse; Vedran Lekić; Patrick L. Whelley; Jacob Giles; Linden Wike; John D. West; Ryan Porter; Maria E. Banks; John Coonan; Naya Deykes; Saffat Shahid; Zachary Vig; Michael Zanetti

doi:10.1029/2025GL116494

Earth and Sustainability

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

Abstract

Lava tubes, a common volcanic feature on terrestrial planets, offer critical insights into lava flow processes and may serve as future potential habitats for space crews and other facilities on the Moon and Mars. Seismic detection of these features is challenging as the irregular morphology and rough cave ceilings and walls generate complex seismic wavefields dominated by strong scattering and reverberation rather than pure reflections. Here we present observations of enhanced backscattering in seismic data collected above terrestrial lava tubes. We show that the spatial and frequency characteristics of wavefield intensity can be related to the dimensions of the lava tubes. Our findings suggest that, when geological indicators such as collapse pits are present, this method would enable mapping lava tubes on Earth and, by proxy, on the Moon and Mars, and that the approach is readily adaptable for future planetary exploration.

Original language	English (US)
Article number	e2025GL116494
Journal	Geophysical Research Letters
Volume	52
Issue number	16
DOIs	https://doi.org/10.1029/2025GL116494
State	Published - Aug 28 2025

Keywords

lava tubes
planetary exploration
planetary geophysics
seismic imaging
terrestrial analog

ASJC Scopus subject areas

Geophysics
General Earth and Planetary Sciences

Access to Document

10.1029/2025GL116494

Cite this

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title = "Enhanced Seismic Backscattering for Lava Tube Detection",

abstract = "Lava tubes, a common volcanic feature on terrestrial planets, offer critical insights into lava flow processes and may serve as future potential habitats for space crews and other facilities on the Moon and Mars. Seismic detection of these features is challenging as the irregular morphology and rough cave ceilings and walls generate complex seismic wavefields dominated by strong scattering and reverberation rather than pure reflections. Here we present observations of enhanced backscattering in seismic data collected above terrestrial lava tubes. We show that the spatial and frequency characteristics of wavefield intensity can be related to the dimensions of the lava tubes. Our findings suggest that, when geological indicators such as collapse pits are present, this method would enable mapping lava tubes on Earth and, by proxy, on the Moon and Mars, and that the approach is readily adaptable for future planetary exploration.",

keywords = "lava tubes, planetary exploration, planetary geophysics, seismic imaging, terrestrial analog",

author = "Jingchuan Wang and Schmerr, \{Nicholas C.\} and Naoma McCall and Sarah Kruse and Vedran Leki{\'c} and Whelley, \{Patrick L.\} and Jacob Giles and Linden Wike and West, \{John D.\} and Ryan Porter and Banks, \{Maria E.\} and John Coonan and Naya Deykes and Saffat Shahid and Zachary Vig and Michael Zanetti",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s).",

year = "2025",

month = aug,

day = "28",

doi = "10.1029/2025GL116494",

language = "English (US)",

volume = "52",

journal = "Geophysical Research Letters",

issn = "0094-8276",

publisher = "John Wiley and Sons Inc.",

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TY - JOUR

T1 - Enhanced Seismic Backscattering for Lava Tube Detection

AU - Wang, Jingchuan

AU - Schmerr, Nicholas C.

AU - McCall, Naoma

AU - Kruse, Sarah

AU - Lekić, Vedran

AU - Whelley, Patrick L.

AU - Giles, Jacob

AU - Wike, Linden

AU - West, John D.

AU - Porter, Ryan

AU - Banks, Maria E.

AU - Coonan, John

AU - Deykes, Naya

AU - Shahid, Saffat

AU - Vig, Zachary

AU - Zanetti, Michael

PY - 2025/8/28

Y1 - 2025/8/28

N2 - Lava tubes, a common volcanic feature on terrestrial planets, offer critical insights into lava flow processes and may serve as future potential habitats for space crews and other facilities on the Moon and Mars. Seismic detection of these features is challenging as the irregular morphology and rough cave ceilings and walls generate complex seismic wavefields dominated by strong scattering and reverberation rather than pure reflections. Here we present observations of enhanced backscattering in seismic data collected above terrestrial lava tubes. We show that the spatial and frequency characteristics of wavefield intensity can be related to the dimensions of the lava tubes. Our findings suggest that, when geological indicators such as collapse pits are present, this method would enable mapping lava tubes on Earth and, by proxy, on the Moon and Mars, and that the approach is readily adaptable for future planetary exploration.

AB - Lava tubes, a common volcanic feature on terrestrial planets, offer critical insights into lava flow processes and may serve as future potential habitats for space crews and other facilities on the Moon and Mars. Seismic detection of these features is challenging as the irregular morphology and rough cave ceilings and walls generate complex seismic wavefields dominated by strong scattering and reverberation rather than pure reflections. Here we present observations of enhanced backscattering in seismic data collected above terrestrial lava tubes. We show that the spatial and frequency characteristics of wavefield intensity can be related to the dimensions of the lava tubes. Our findings suggest that, when geological indicators such as collapse pits are present, this method would enable mapping lava tubes on Earth and, by proxy, on the Moon and Mars, and that the approach is readily adaptable for future planetary exploration.

KW - lava tubes

KW - planetary exploration

KW - planetary geophysics

KW - seismic imaging

KW - terrestrial analog

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DO - 10.1029/2025GL116494

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JO - Geophysical Research Letters

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