Empirical H/V spectral ratios at the InSight landing site and implications for the martian subsurface structure

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Empirical H/V spectral ratios at the InSight landing site and implications for the martian subsurface structure. / Carrasco, Sebastián; Knapmeyer-Endrun, Brigitte; Margerin, Ludovic; Schmelzbach, Cédric; Onodera, Keisuke; Pan, Lu; Lognonné, Philippe; Menina, Sabrina; Giardini, Domenico; Stutzmann, Eléonore; Clinton, John; Stähler, Simon; Schimmel, Martin; Golombek, Matthew; Hobiger, Manuel; Hallo, Miroslav; Kedar, Sharon; Banerdt, W. Bruce.

In: Geophysical Journal International, Vol. 232, No. 2, 2022, p. 1293-1310.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Carrasco, S, Knapmeyer-Endrun, B, Margerin, L, Schmelzbach, C, Onodera, K, Pan, L, Lognonné, P, Menina, S, Giardini, D, Stutzmann, E, Clinton, J, Stähler, S, Schimmel, M, Golombek, M, Hobiger, M, Hallo, M, Kedar, S & Banerdt, WB 2022, 'Empirical H/V spectral ratios at the InSight landing site and implications for the martian subsurface structure', Geophysical Journal International, vol. 232, no. 2, pp. 1293-1310. https://doi.org/10.1093/gji/ggac391

APA

Carrasco, S., Knapmeyer-Endrun, B., Margerin, L., Schmelzbach, C., Onodera, K., Pan, L., Lognonné, P., Menina, S., Giardini, D., Stutzmann, E., Clinton, J., Stähler, S., Schimmel, M., Golombek, M., Hobiger, M., Hallo, M., Kedar, S., & Banerdt, W. B. (2022). Empirical H/V spectral ratios at the InSight landing site and implications for the martian subsurface structure. Geophysical Journal International, 232(2), 1293-1310. https://doi.org/10.1093/gji/ggac391

Vancouver

Carrasco S, Knapmeyer-Endrun B, Margerin L, Schmelzbach C, Onodera K, Pan L et al. Empirical H/V spectral ratios at the InSight landing site and implications for the martian subsurface structure. Geophysical Journal International. 2022;232(2):1293-1310. https://doi.org/10.1093/gji/ggac391

Author

Carrasco, Sebastián ; Knapmeyer-Endrun, Brigitte ; Margerin, Ludovic ; Schmelzbach, Cédric ; Onodera, Keisuke ; Pan, Lu ; Lognonné, Philippe ; Menina, Sabrina ; Giardini, Domenico ; Stutzmann, Eléonore ; Clinton, John ; Stähler, Simon ; Schimmel, Martin ; Golombek, Matthew ; Hobiger, Manuel ; Hallo, Miroslav ; Kedar, Sharon ; Banerdt, W. Bruce. / Empirical H/V spectral ratios at the InSight landing site and implications for the martian subsurface structure. In: Geophysical Journal International. 2022 ; Vol. 232, No. 2. pp. 1293-1310.

Bibtex

@article{ef3ccac3fa684177b55fa23234968b17,
title = "Empirical H/V spectral ratios at the InSight landing site and implications for the martian subsurface structure",
abstract = "The horizontal-to-vertical (H/V) spectral ratio inversion is a traditional technique for deriving the local subsurface structure on Earth. We calculated the H/V from the ambient vibrations at different wind levels at the InSight landing site, on Mars, and also computed the H/V from the S-wave coda of the martian seismic events (marsquakes). Different H/V curves were obtained for different wind periods and from the marsquakes. From the ambient vibrations, the recordings during low-wind periods are close to the instrument self-noise level. During high-wind periods, the seismic recordings are highly contaminated by the interaction of the lander with the wind and the martian ground. Therefore, these recordings are less favourable for traditional H/V analysis. Instead, the recordings of the S-wave coda of marsquakes were preferred to derive the characteristic H/V curve of this site between 0.4 and 10 Hz. The final H/V curve presents a characteristic trough at 2.4 Hz and a strong peak at 8 Hz. Using a full diffuse wavefield approach as the forward computation and the Neighbourhood Algorithm as the sampling technique, we invert for the 1-D shear wave velocity structure at the InSight landing site. Based on our inversion results, we propose a strong site effect at the InSight site to be due to the presence of a shallow high-velocity layer (SHVL) over low-velocity units. The SHVL is likely placed below a layer of coarse blocky ejecta and can be associated with Early Amazonian basaltic lava flows. The units below the SHVL have lower velocities, possibly related to a Late Hesperian or Early Amazonian epoch with a different magmatic regime and/or a greater impact rate and more extensive weathering. An extremely weak buried low velocity layer (bLVL) between these lava flows explains the data around the 2.4 Hz trough, whereas a more competent bLVL would not generate this latter feature. These subsurface models are in good agreement with results from hammering experiment and compliance measurements at the InSight landing site. Finally, this site effect is revealed only by seismic events data and explains the larger horizontal than vertical ground motion recorded for certain type of marsquakes.",
author = "Sebasti{\'a}n Carrasco and Brigitte Knapmeyer-Endrun and Ludovic Margerin and C{\'e}dric Schmelzbach and Keisuke Onodera and Lu Pan and Philippe Lognonn{\'e} and Sabrina Menina and Domenico Giardini and El{\'e}onore Stutzmann and John Clinton and Simon St{\"a}hler and Martin Schimmel and Matthew Golombek and Manuel Hobiger and Miroslav Hallo and Sharon Kedar and Banerdt, {W. Bruce}",
year = "2022",
doi = "10.1093/gji/ggac391",
language = "English",
volume = "232",
pages = "1293--1310",
journal = "Geophysical Journal International",
issn = "0956-540X",
publisher = "Oxford University Press",
number = "2",

}

RIS

TY - JOUR

T1 - Empirical H/V spectral ratios at the InSight landing site and implications for the martian subsurface structure

AU - Carrasco, Sebastián

AU - Knapmeyer-Endrun, Brigitte

AU - Margerin, Ludovic

AU - Schmelzbach, Cédric

AU - Onodera, Keisuke

AU - Pan, Lu

AU - Lognonné, Philippe

AU - Menina, Sabrina

AU - Giardini, Domenico

AU - Stutzmann, Eléonore

AU - Clinton, John

AU - Stähler, Simon

AU - Schimmel, Martin

AU - Golombek, Matthew

AU - Hobiger, Manuel

AU - Hallo, Miroslav

AU - Kedar, Sharon

AU - Banerdt, W. Bruce

PY - 2022

Y1 - 2022

N2 - The horizontal-to-vertical (H/V) spectral ratio inversion is a traditional technique for deriving the local subsurface structure on Earth. We calculated the H/V from the ambient vibrations at different wind levels at the InSight landing site, on Mars, and also computed the H/V from the S-wave coda of the martian seismic events (marsquakes). Different H/V curves were obtained for different wind periods and from the marsquakes. From the ambient vibrations, the recordings during low-wind periods are close to the instrument self-noise level. During high-wind periods, the seismic recordings are highly contaminated by the interaction of the lander with the wind and the martian ground. Therefore, these recordings are less favourable for traditional H/V analysis. Instead, the recordings of the S-wave coda of marsquakes were preferred to derive the characteristic H/V curve of this site between 0.4 and 10 Hz. The final H/V curve presents a characteristic trough at 2.4 Hz and a strong peak at 8 Hz. Using a full diffuse wavefield approach as the forward computation and the Neighbourhood Algorithm as the sampling technique, we invert for the 1-D shear wave velocity structure at the InSight landing site. Based on our inversion results, we propose a strong site effect at the InSight site to be due to the presence of a shallow high-velocity layer (SHVL) over low-velocity units. The SHVL is likely placed below a layer of coarse blocky ejecta and can be associated with Early Amazonian basaltic lava flows. The units below the SHVL have lower velocities, possibly related to a Late Hesperian or Early Amazonian epoch with a different magmatic regime and/or a greater impact rate and more extensive weathering. An extremely weak buried low velocity layer (bLVL) between these lava flows explains the data around the 2.4 Hz trough, whereas a more competent bLVL would not generate this latter feature. These subsurface models are in good agreement with results from hammering experiment and compliance measurements at the InSight landing site. Finally, this site effect is revealed only by seismic events data and explains the larger horizontal than vertical ground motion recorded for certain type of marsquakes.

AB - The horizontal-to-vertical (H/V) spectral ratio inversion is a traditional technique for deriving the local subsurface structure on Earth. We calculated the H/V from the ambient vibrations at different wind levels at the InSight landing site, on Mars, and also computed the H/V from the S-wave coda of the martian seismic events (marsquakes). Different H/V curves were obtained for different wind periods and from the marsquakes. From the ambient vibrations, the recordings during low-wind periods are close to the instrument self-noise level. During high-wind periods, the seismic recordings are highly contaminated by the interaction of the lander with the wind and the martian ground. Therefore, these recordings are less favourable for traditional H/V analysis. Instead, the recordings of the S-wave coda of marsquakes were preferred to derive the characteristic H/V curve of this site between 0.4 and 10 Hz. The final H/V curve presents a characteristic trough at 2.4 Hz and a strong peak at 8 Hz. Using a full diffuse wavefield approach as the forward computation and the Neighbourhood Algorithm as the sampling technique, we invert for the 1-D shear wave velocity structure at the InSight landing site. Based on our inversion results, we propose a strong site effect at the InSight site to be due to the presence of a shallow high-velocity layer (SHVL) over low-velocity units. The SHVL is likely placed below a layer of coarse blocky ejecta and can be associated with Early Amazonian basaltic lava flows. The units below the SHVL have lower velocities, possibly related to a Late Hesperian or Early Amazonian epoch with a different magmatic regime and/or a greater impact rate and more extensive weathering. An extremely weak buried low velocity layer (bLVL) between these lava flows explains the data around the 2.4 Hz trough, whereas a more competent bLVL would not generate this latter feature. These subsurface models are in good agreement with results from hammering experiment and compliance measurements at the InSight landing site. Finally, this site effect is revealed only by seismic events data and explains the larger horizontal than vertical ground motion recorded for certain type of marsquakes.

U2 - 10.1093/gji/ggac391

DO - 10.1093/gji/ggac391

M3 - Journal article

VL - 232

SP - 1293

EP - 1310

JO - Geophysical Journal International

JF - Geophysical Journal International

SN - 0956-540X

IS - 2

ER -

ID: 321793451