Your search keyword '"Pinot, Baptiste"' showing total 28 results

1. The In Situ Evaluation of the SEIS Noise Model

Author

Pinot, Baptiste, Mimoun, David, Murdoch, Naomi, Onodera, Keisuke, Johnson, Catherine, Mittelholz, Anna, Drilleau, Melanie, Stott, Alexander, Pou, Laurent, de Raucourt, Sebastien, Lognonné, Philippe, Widmer-Schnidrig, Rudolf, Lange, Lucas, Panning, Mark, and Banerdt, Bruce

Published

2024

2. Seismic detection of a deep mantle discontinuity within Mars by InSight

Author

Huang, Quancheng, Schmerr, Nicholas C, King, Scott D, Kim, Doyeon, Rivoldini, Attilio, Plesa, Ana-Catalina, Samuel, Henri, Maguire, Ross R, Karakostas, Foivos, Lekić, Vedran, Charalambous, Constantinos, Collinet, Max, Myhill, Robert, Antonangeli, Daniele, Drilleau, Mélanie, Bystricky, Misha, Bollinger, Caroline, Michaut, Chloé, Gudkova, Tamara, Irving, Jessica CE, Horleston, Anna, Fernando, Benjamin, Leng, Kuangdai, Nissen-Meyer, Tarje, Bejina, Frederic, Bozdağ, Ebru, Beghein, Caroline, Waszek, Lauren, Siersch, Nicki C, Scholz, John-Robert, Davis, Paul M, Lognonné, Philippe, Pinot, Baptiste, Widmer-Schnidrig, Rudolf, Panning, Mark P, Smrekar, Suzanne E, Spohn, Tilman, Pike, William T, Giardini, Domenico, and Banerdt, W Bruce

Subjects

Earth Sciences, Physical Sciences, Astronomical Sciences, Geology, Geophysics, Earth, Planet, Extraterrestrial Environment, Iron, Mars, Minerals, interior of Mars, mantle transition zone, thermal evolution of Mars

Abstract

Constraining the thermal and compositional state of the mantle is crucial for deciphering the formation and evolution of Mars. Mineral physics predicts that Mars' deep mantle is demarcated by a seismic discontinuity arising from the pressure-induced phase transformation of the mineral olivine to its higher-pressure polymorphs, making the depth of this boundary sensitive to both mantle temperature and composition. Here, we report on the seismic detection of a midmantle discontinuity using the data collected by NASA's InSight Mission to Mars that matches the expected depth and sharpness of the postolivine transition. In five teleseismic events, we observed triplicated P and S waves and constrained the depth of this discontinuity to be 1,006 [Formula: see text] 40 km by modeling the triplicated waveforms. From this depth range, we infer a mantle potential temperature of 1,605 [Formula: see text] 100 K, a result consistent with a crust that is 10 to 15 times more enriched in heat-producing elements than the underlying mantle. Our waveform fits to the data indicate a broad gradient across the boundary, implying that the Martian mantle is more enriched in iron compared to Earth. Through modeling of thermochemical evolution of Mars, we observe that only two out of the five proposed composition models are compatible with the observed boundary depth. Our geodynamic simulations suggest that the Martian mantle was relatively cold 4.5 Gyr ago (1,720 to 1,860 K) and are consistent with a present-day surface heat flow of 21 to 24 mW/m2.

Published

2022

3. Investigating Diurnal and Seasonal Turbulence Variations of the Martian Atmosphere Using a Spectral Approach

Author

Murdoch, Naomi, primary, Stott, Alexander E., additional, Mimoun, David, additional, Pinot, Baptiste, additional, Chatain, Audrey, additional, Spiga, Aymeric, additional, Temel, Orkun, additional, Garcia, Jorge Pla, additional, Onodera, Keisuke, additional, Lorenz, Ralph, additional, Gillier, Martin, additional, Newman, Claire, additional, Garcia, Raphael F., additional, Lange, Lucas, additional, and Banfield, Don, additional

Published

2023

4. Using machine learning to separate atmospherically generated noise from marsquakes

Author

Stott, Alexander, primary, Garcia, Raphael, additional, Chédozeau, Armand, additional, Spiga, Aymeric, additional, Murdoch, Naomi, additional, Pinot, Baptiste, additional, Mimoun, David, additional, Charalambous, Constantinos, additional, Horleston, Anna, additional, King, Scott, additional, Kawamura, Taichi, additional, Dahmen, Nikolaj, additional, Barkaoui, Salma, additional, Lognonné, Philippe, additional, and Banerdt, William, additional

Published

2022

5. Machine learning and marsquakes: a tool to predict atmospheric-seismic noise for the NASA InSight mission

Author

Stott, Alexander, primary, Garcia, Raphael, additional, Chédozeau, Armand, additional, Spiga, Aymeric, additional, Murdoch, Naomi, additional, Pinot, Baptiste, additional, Mimoun, David, additional, Charalambous, Constantinos, additional, Horleston, Anna, additional, King, Scott, additional, Kawamura, Taichi, additional, Dahmen, Nikolaj, additional, Barkaoui, Salma, additional, lognonne, Philippe, additional, and Banerdt, Bruce, additional

Published

2022

6. Tilt removal on 6-axis ground motion measurements: experiments at iXblue

Author

Lenogue, Guillaume, primary, Pinot, Baptiste, additional, Guattari, Frederic, additional, and Mimoun, David, additional

Published

2022

7. Analytical developments on 6C computation inspired by navigation algorithms

Author

Pinot, Baptiste, primary, Guattari, Frederic, additional, Honthaas, Joachin, additional, and Mimoun, David, additional

Published

2022

8. Upper mantle structure of Mars from InSight seismic data

Author

Khan, Amir, primary, Ceylan, Savas, additional, van Driel, Martin, additional, Giardini, Domenico, additional, Lognonné, Philippe, additional, Samuel, Henri, additional, Schmerr, Nicholas C., additional, Stähler, Simon C., additional, Duran, Andrea C., additional, Huang, Quancheng, additional, Kim, Doyeon, additional, Broquet, Adrien, additional, Charalambous, Constantinos, additional, Clinton, John F., additional, Davis, Paul M., additional, Drilleau, Mélanie, additional, Karakostas, Foivos, additional, Lekic, Vedran, additional, McLennan, Scott M., additional, Maguire, Ross R., additional, Michaut, Chloé, additional, Panning, Mark P., additional, Pike, William T., additional, Pinot, Baptiste, additional, Plasman, Matthieu, additional, Scholz, John-Robert, additional, Widmer-Schnidrig, Rudolf, additional, Spohn, Tilman, additional, Smrekar, Suzanne E., additional, and Banerdt, William B., additional

Published

2021

9. Thickness and structure of the martian crust from InSight seismic data

Author

Knapmeyer-Endrun, Brigitte, primary, Panning, Mark P., additional, Bissig, Felix, additional, Joshi, Rakshit, additional, Khan, Amir, additional, Kim, Doyeon, additional, Lekić, Vedran, additional, Tauzin, Benoit, additional, Tharimena, Saikiran, additional, Plasman, Matthieu, additional, Compaire, Nicolas, additional, Garcia, Raphael F., additional, Margerin, Ludovic, additional, Schimmel, Martin, additional, Stutzmann, Éléonore, additional, Schmerr, Nicholas, additional, Bozdağ, Ebru, additional, Plesa, Ana-Catalina, additional, Wieczorek, Mark A., additional, Broquet, Adrien, additional, Antonangeli, Daniele, additional, McLennan, Scott M., additional, Samuel, Henri, additional, Michaut, Chloé, additional, Pan, Lu, additional, Smrekar, Suzanne E., additional, Johnson, Catherine L., additional, Brinkman, Nienke, additional, Mittelholz, Anna, additional, Rivoldini, Attilio, additional, Davis, Paul M., additional, Lognonné, Philippe, additional, Pinot, Baptiste, additional, Scholz, John-Robert, additional, Stähler, Simon, additional, Knapmeyer, Martin, additional, van Driel, Martin, additional, Giardini, Domenico, additional, and Banerdt, W. Bruce, additional

Published

2021

10. The interior of Mars as seen by InSight (Invited)

Author

Staehler, Simon C., Khan, A., Knapmeyer‐Endrun, Brigitte, Panning, Mark P., Banerdt, William B., Lognonné, P., Giardini, Domenico, Antonangeli, D., Beucler, E., Bissig, F., Bozdag, E., Brinkmann, N., Ceylan, S., Charalambous, C., Clinton, John F., Compaire, Nicolas, Dahmen, N. L., Davis, P., van Driel, M., Drilleau, M., Garcia, Raphael F., Huang, Quancheng, Joshi, Rakshit, Gudkova, T., Irving, Jessica C. E., Johnson, C., Kawamura, T., Kim, Doyeon, Knapmeyer, Martin, Maguire, R., Lekic, Vedran, Margerin, L., Marusiak, A, McLennan, S M, Mittelholz, A., Michaut, Chloe, Plasman, M., Pan, L., Duran, C., Perrin, C., Pike, T., Plesa, Ana-Catalina, Pinot, Baptiste, Rivoldini, A., Scholz, J.-R., Schimmel, Martin, Schmerr, N., Stutzmann, Éléonore, Samuel, H., Smrekar, S., Spohn, Tilman, Tauzin, B., Tharimena, S., Widmer-Schnidrig, R, Wieczorek, M., Xu, Zongbo, Zenhäusern, Geraldine, Karakostas, F., and InSight, Science Team

Abstract

InSight is the first planetary mission dedicated to exploring the whole interior of a planet using geophysical methods, specifically seismology and geodesy. To this end, we observed seismic waves of distant marsquakes and inverted for interior models using differential travel times of phases reflected at the surface (PP, SS...) or the core mantle-boundary (ScS), as well as those converted at crustal interfaces. Compared to previous orbital observations1-3, the seismic data added decisive new insights with consequences for the formation of Mars: The global average crustal thickness of 24-75 km is at the low end of pre-mission estimates5. Together with the the thick lithosphere of 450-600 km5, this requires an enrichment of heat-producing elements in the crust by a factor of 13-20, compared to the primitive mantle. The iron-rich liquid core is 1790-1870 km in radius6, which rules out the existence of an insulating bridgmanite-dominated lower mantle on Mars. The large, and therefore low-density core needs a high amount of light elements. Given the geochemical boundary conditions, Sulfur alone cannot explain the estimated density of ~6 g/cm3 and volatile elements, such as oxygen, carbon or hydrogen are needed in significant amounts. This observation is difficult to reconcile with classical models of late formation from the same material as Earth. We also give an overview of open questions after three years of InSight operation on the surface of Mars, such as the potential existence of an inner core or compositional layers above the CMB

Published

2021

11. Thickness and structure of the martian crust from InSight seismic data

Author

Knapmeyer-Endrun, Brigitte, Panning, Mark P., Bissig, Felix, Joshi, Rakshit, Khan, Amir, Kim, Doyeon, Lekic, Vedran, Tauzin, Benoit, Tharimena, Saikiran, Plasman, Matthieu, Compaire, Nicolas, Garcia, Raphael F., Margerin, Ludovic, Schimmel, Martin, Stutzmann, Eleonore, Schmerr, Nicholas, Bozdag, Ebru, Plesa, Ana-Catalina, Wieczorek, Mark A., Broquet, Adrien, Antonangeli, Daniele, McLennan, Scott M., Samuel, Henri, Michaut, Chloe, Pan, Lu, Smrekar, Suzanne E., Johnson, Catherine L., Brinkman, Nienke, Mittelholz, Anna, Rivoldini, Attilio, Davis, Paul M., Lognonne, Philippe, Pinot, Baptiste, Scholz, John-Robert, Stahler, Simon, Knapmeyer, Martin, van Driel, Martin, Giardini, Domenico, Banerdt, W. Bruce, Knapmeyer-Endrun, Brigitte, Panning, Mark P., Bissig, Felix, Joshi, Rakshit, Khan, Amir, Kim, Doyeon, Lekic, Vedran, Tauzin, Benoit, Tharimena, Saikiran, Plasman, Matthieu, Compaire, Nicolas, Garcia, Raphael F., Margerin, Ludovic, Schimmel, Martin, Stutzmann, Eleonore, Schmerr, Nicholas, Bozdag, Ebru, Plesa, Ana-Catalina, Wieczorek, Mark A., Broquet, Adrien, Antonangeli, Daniele, McLennan, Scott M., Samuel, Henri, Michaut, Chloe, Pan, Lu, Smrekar, Suzanne E., Johnson, Catherine L., Brinkman, Nienke, Mittelholz, Anna, Rivoldini, Attilio, Davis, Paul M., Lognonne, Philippe, Pinot, Baptiste, Scholz, John-Robert, Stahler, Simon, Knapmeyer, Martin, van Driel, Martin, Giardini, Domenico, and Banerdt, W. Bruce

Abstract

A planet's crust bears witness to the history of planetary formation and evolution, but for Mars, no absolute measurement of crustal thickness has been available. Here, we determine the structure of the crust beneath the InSight landing site on Mars using both marsquake recordings and the ambient wavefield. By analyzing seismic phases that are reflected and converted at subsurface interfaces, we find that the observations are consistent with models with at least two and possibly three interfaces. If the second interface is the boundary of the crust, the thickness is 20 +/- 5 kilometers, whereas if the third interface is the boundary, the thickness is 39 +/- 8 kilometers. Global maps of gravity and topography allow extrapolation of this point measurement to the whole planet, showing that the average thickness of the martian crust lies between 24 and 72 kilometers. Independent bulk composition and geodynamic constraints show that the thicker model is consistent with the abundances of crustal heat-producing elements observed for the shallow surface, whereas the thinner model requires greater concentration at depth.

Published

2021

12. Autocorrelation of the Ground Vibrations Recorded by the SEIS-InSight Seismometer on Mars

Author

Agence Nationale de la Recherche (France), Université de Toulouse, Schimmel, Martin [0000-0003-2601-4462], Compaire, Nicolas, Margerin, Ludovic, Garcia, R. F., Pinot, Baptiste, Calvet, M., Orhand-Mainsant, Guenolé, Kim, D., Lekic, Vedran, Tauzin, B., Schimmel, Martin, Stutzmann, E., Knapmeyer‐Endrun, Brigitte, Lognonné, P., Pike, William T., Schmerr, N., Gizon, L., Banerdt, W. B., Agence Nationale de la Recherche (France), Université de Toulouse, Schimmel, Martin [0000-0003-2601-4462], Compaire, Nicolas, Margerin, Ludovic, Garcia, R. F., Pinot, Baptiste, Calvet, M., Orhand-Mainsant, Guenolé, Kim, D., Lekic, Vedran, Tauzin, B., Schimmel, Martin, Stutzmann, E., Knapmeyer‐Endrun, Brigitte, Lognonné, P., Pike, William T., Schmerr, N., Gizon, L., and Banerdt, W. B.

Abstract

Since early February 2019, the SEIS (Seismic Experiment for Interior Structure) seismometer deployed at the surface of Mars in the framework of the InSight mission has been continuously recording the ground motion at Elysium Planitia. In this study, we take advantage of this exceptional data set to put constraints on the crustal properties of Mars using seismic interferometry (SI). To carry out this task, we first examine the continuous records from the very broadband seismometer. Several deterministic sources of environmental noise are identified and specific preprocessing strategies are presented to mitigate their influence. Applying the principles of SI to the single-station configuration of InSight, we compute, for each Sol and each hour of the martian day, the diagonal elements of the time-domain correlation tensor of random ambient vibrations recorded by SEIS. A similar computation is performed on the diffuse waveforms generated by more than a hundred Marsquakes. A careful signal-to-noise ratio analysis and an inter-comparison between the two datasets suggest that the results from SI are most reliable in a narrow frequency band around 2.4 Hz, where an amplification of both ambient vibrations and seismic events is observed. The average autocorrelation functions (ACFs) contain well identifiable seismic arrivals, that are very consistent between the two datasets. Interpreting the vertical and horizontal ACFs as, respectively, the P- and S- seismic reflectivity below InSight, we propose a simple stratified velocity model of the crust, which is mostly compatible with previous results from receiver function analysis. Our results are discussed and compared to recent works from the literature.

Published

2021

13. Autocorrelation of the ground vibration recorded by the SEIS-InSight seismometer on Mars for imaging and monitoring applications

Author

Compaire, Nicolas, Margerin, Ludovic, García, Raphael, Calvet, Marie, Pinot, Baptiste, Orhand-Mainsant, Guenolé, Kim, Doyeon, Lekic, Vedran, Tauzin, Benoit, Schimmel, Martin, Stutzmann, E., Knapmeyer‐Endrun, Brigitte, Lognonné, P., Pike, William T., Schmerr, Nicholas C., Gizon, Laurent, Banerdt, B., Compaire, Nicolas, Margerin, Ludovic, García, Raphael, Calvet, Marie, Pinot, Baptiste, Orhand-Mainsant, Guenolé, Kim, Doyeon, Lekic, Vedran, Tauzin, Benoit, Schimmel, Martin, Stutzmann, E., Knapmeyer‐Endrun, Brigitte, Lognonné, P., Pike, William T., Schmerr, Nicholas C., Gizon, Laurent, and Banerdt, B.

Abstract

Since early February 2019, the SEIS seismometer deployed at the surface of Mars in the framework of the NASA-InSight mission has been continuously recording the ground motion at Elysium Planitia. In this work, we take advantage of this exceptional dataset to put constraints on the crustal properties of Mars using seismic interferometry (SI). This method use the seismic waves, either from background vibrations of the planet or from quakes, that are scattered in the medium in order to recover the ground response between two seismic sensors. Applying the principles of SI to the single-station configuration of SEIS, we compute, for each Sol (martian day) and each local hour, all the components of the time-domain autocorrelation tensor of random ambient vibrations in various frequency bands. A similar computation is performed on the diffuse waveforms generated by more than a hundred Marsquakes. For imaging application a careful signal-to-noise ratio analysis and an inter-comparison between the two datasets are applied. These analyses suggest that the reconstructed ground responses are most reliable in a relatively narrow frequency band around 2.4Hz, where an amplification of both ambient vibrations and seismic events is observed. The average Auto-Correlation Functions (ACFs) from both ambient vibrations and seismic events contain well identifiable seismic arrivals, that are very consistent between the two datasets. We interpret the vertical and horizontal ACFs as the ground reflection response below InSight for the compressional waves and the shear waves respectively. We propose a simple stratified velocity model of the crust, which is most compatible with the arrival times of the detected phases, as well as with previous seismological studies of the SEIS record. The hourly computation of the ACFs over one martian year also allows us to study the diurnal and seasonal variations of the reconstructed ground response with a technique call Passive Image Interferometry (PII).

Published

2021

14. InSight seismic data from Mars: Effect and treatment of transient data disturbances

Author

Widmer-Schnidrig, Rudolf, Scholz, J. R., Davis, Paul, Lognonné, P., Pinot, Baptiste, García, Raphael, Hurst, K., Pou, Laurent, Nimmo, F., Barkaoui, Salma, De Raucourt, Sebastien, Knapmeyer‐Endrun, Brigitte, Knapmeyer, M., Orhand-Mainsant, Guenolé, Compaire, Nicolas, Cuvier, Arthur, Beucler, E., Bonnin, Mickaël J. A., Joshi, Rakshit, Sainton, G., Stutzmann, E., Schimmel, Martin, Horleston, Anna C., Böse, M., Ceylan, S., Clinton, John F., van Driel, M., Kawamura, T., Khan, A., Staehler, Simon C., Giardini, Domenico, Charalambous, C., Stott, Alexander, Pike, William T., Christensen, U., and Banerdt, William B.

Subjects

Seismicity, Mars

Abstract

The instrument package SEIS (Seismic Experiment for Internal Structure) with the two co-located seismometers VBB and SP is installed on the surface of Mars as part of NASA's InSight mission. When compared to terrestrial installations, SEIS is deployed in a very harsh wind and temperature environment that leads to inevitable degradation of the quality of the recorded data. The daily atmospheric temperature variations of approx. 80K are attenuated by different insulation layers to approx. 15K peak-to-peak at the sensor level. Typical wind speeds vary between 0 and 5 m/s leading to a diurnal variation in the broad-band rms noise level by two orders of magnitude. One ubiquitous artifact in the raw broad-band data is an abundance of one-sided, transient pulses often accompanied by high-frequency spikes. We show that these pulses, which we term "glitches", can be modeled as the response of the instrument to a step in acceleration, while the spikes can be modeled as the response to a simultaneous step in displacement. We attribute the glitches primarily to intermittent stress relaxation events internal to SEIS caused by the large diurnal temperature variations to which the instrument is exposed during a Martian sol. Only a small fraction of glitches correspond to a motion of the SEIS package as a whole caused by minuscule tilts of the instrument. Whilst such kind of data disturbances are typically discarded when occurring in terrestrial data, this is no option for the data returned from the Red Planet. We therefore do not only demonstrate their effects on the seismic data and analyze their origins, but also propose algorithms that are able to detect and remove many of these (mostly) non-seismic signals. We further published our codes (both Python and MATLAB) so that interested researchers can make their own choices on how to treat the data and to which extent.

Published

2020

15. Joint inversion of receiver functions and apparent incidence angles to investigate the crustal structure of Mars

Author

Joshi, Rakshit, primary, Knapmeyer-Endrun, Brigitte, additional, Mosegaard, Klaus, additional, Bissig, Felix, additional, Khan, Amir, additional, Panning, Mark, additional, Staehler, Simon, additional, Tauzin, Benoit, additional, Lekic, Vedran, additional, Scholz, John-Robert, additional, Davis, Paul, additional, Widmer-Schnidrig, Rudolf, additional, Garcia, Raphael, additional, Pinot, Baptiste, additional, Lognonné, Philippe, additional, and Christensen, Ulrich, additional

Published

2021

16. Atmospherically driven ground motion at InSight: a machine learning perspective

Author

Stott, Alexander E., primary, Garcia, Raphael F., additional, Pinot, Baptiste, additional, Murdoch, Naomi, additional, Mimoun, David, additional, Spiga, Aymeric, additional, Banfield, Donald, additional, Navarro, Sara, additional, Mora-Sotomayor, Luis, additional, Charalambous, Constantinos, additional, Pike, William T., additional, Lognonné, Philippe, additional, and Horleston, Anna, additional

Published

2021

17. Autocorrelation of the ground vibration recorded by the SEIS-InSight seismometer on Mars for imaging and monitoring applications

Author

Compaire, Nicolas, primary, Margerin, Ludovic, additional, Garcia, Raphaël F., additional, Calvet, Marie, additional, Pinot, Baptiste, additional, Orhand-Mainsant, Guénolé, additional, Kim, Doyeon, additional, Lekic, Vedran, additional, Tauzin, Benoit, additional, Schimmel, Martin, additional, Stutzmann, Eléonore, additional, Knapmeyer-Endrun, Brigitte, additional, Lognonné, Philippe, additional, Pike, William T., additional, Schmerr, Nicholas, additional, Gizon, Laurent, additional, and Banerdt, Bruce, additional

Published

2021

18. New seismological constraints on the crustal structure of Mars and the Moon

Author

Knapmeyer-Endrun, B., Panning, M., Bissig, Felix, Joshi, Rakshit, Khan, A., Kim, Doyeon, Lekic, V., Tauzin, B., Tharimena, S., Plasman, Matthieu, Compaire, Nicolas, Garcia, Raphaël F., Margerin, L., Schimmel, M., Stutzmann, Éléonore, Schmerr, N., Antonangeli, D., Bozdag, E., McLennan, S M, Peter, Daniel, Plesa, Ana-Catalina, Samuel, H., Wieczorek, M., Davis, Paul, Lognonne, P., Pinot, Baptiste, Scholz, J.-R., Stähler, S., Knapmeyer, Martin, Brinkmann, Nienke, van Driel, M, Giardini, D., Johnson, Catherine L., Smrekar, S., and Banerdt, B.

Subjects

receiver functions, crustal thickness, Mars, seismological constraints, InSight

Abstract

Planetary crusts are the results of mantle differentiation, so their thickness provides important constraints on the thermochemical evolution of a planet, including its heat budget and mantle rheology. Information on crustal layering and seismic velocities can also provide important constraints on porosity and geochemistry of the crust. Here, we use data from the InSight mission, which landed in November 2018, to provide seismological constraints on the crustal layering and thickness of Mars for the first time. Results are mainly based on Ps-receiver functions from three events with magnitudes between 3.1 and 3.6 at distances between 27.5° and 47° (±10°) from the lander, originating in the Cerberus Fossae region, the only events, so far, with clear, impulsive P-wave onsets and known epicenter. Ps-receiver functions use converted phases in the P-wave coda to derive information on discontinuities beneath the seismometer. Due to the limited number of events and the small epicentral distance range covered, inversions of the data are still ambiguous. Two sets of models can explain the waveforms, one consisting of a two-layer crust of about 20 to 23 km thickness, the other having a three-layer crust of about 40 to 45 km thickness. By excluding crustal thicknesses in excess of 45 km at the landing site, we can constrain the global average crustal thickness of Mars to be less than 70 km. Both model types also agree with S-receiver functions for two events and seismic P-waves reflected in the crust and extracted from autocorrelations using the coda of different types of marsquakes as well as the background wavefield. Furthermore, the results are compatible with independently conducted moment tensor inversions for a limited number of events as well as modeling of the wave-propagation of high-frequency events. We find low seismic P-wave velocities below 3.4 km/s within the upper approximately 10 km, likely indicating a high porosity. For the Moon, we present Sp-receiver functions for three Apollo landing sites, including the first application of this method to Apollo 15 and 16 data. Data are compatible with a two-layer crust beneath a thin, low-velocity regolith layer and a crustal thickness of 35 to 45 km, with an increased thickness at the Apollo 15 and 16 sites compared to the Apollo12 location.

Published

2020

19. Detection, Analysis, and Removal of Glitches From InSight's Seismic Data From Mars

Author

Scholz, John-Robert, Widmer-Schnidrig, Rudolf, Davis, Paul, Lognonne, Philippe, Pinot, Baptiste, Garcia, Raphael F., Hurst, Kenneth, Pou, Laurent, Nimmo, Francis, Barkaoui, Salma, De Raucourt, Sebastien, Knapmeyer-Endrun, Brigitte, Knapmeyer, Martin, Orhand-Mainsant, Guenole, Compaire, Nicolas, Cuvier, Arthur, Beucler, Eric, Bonnin, Mickael, Joshi, Rakshit, Sainton, Gregory, Stutzmann, Eleonore, Schimmel, Martin, Horleston, Anna, Bose, Maren, Ceylan, Savas, Clinton, John, Van Driel, Martin, Kawamura, Taichi, Khan, Amir, Stahler, Simon C., Giardini, Domenico, Charalambous, Constantinos, Stott, Alexander E., Pike, William T., Christensen, Ulrich R., Banerdt, W. Bruce, Scholz, John-Robert, Widmer-Schnidrig, Rudolf, Davis, Paul, Lognonne, Philippe, Pinot, Baptiste, Garcia, Raphael F., Hurst, Kenneth, Pou, Laurent, Nimmo, Francis, Barkaoui, Salma, De Raucourt, Sebastien, Knapmeyer-Endrun, Brigitte, Knapmeyer, Martin, Orhand-Mainsant, Guenole, Compaire, Nicolas, Cuvier, Arthur, Beucler, Eric, Bonnin, Mickael, Joshi, Rakshit, Sainton, Gregory, Stutzmann, Eleonore, Schimmel, Martin, Horleston, Anna, Bose, Maren, Ceylan, Savas, Clinton, John, Van Driel, Martin, Kawamura, Taichi, Khan, Amir, Stahler, Simon C., Giardini, Domenico, Charalambous, Constantinos, Stott, Alexander E., Pike, William T., Christensen, Ulrich R., and Banerdt, W. Bruce

Abstract

The instrument package SEIS (Seismic Experiment for Internal Structure) with the three very broadband and three short-period seismic sensors is installed on the surface on Mars as part of NASA's InSight Discovery mission. When compared to terrestrial installations, SEIS is deployed in a very harsh wind and temperature environment that leads to inevitable degradation of the quality of the recorded data. One ubiquitous artifact in the raw data is an abundance of transient one-sided pulses often accompanied by high-frequency spikes. These pulses, which we term glitches, can be modeled as the response of the instrument to a step in acceleration, while the spikes can be modeled as the response to a simultaneous step in displacement. We attribute the glitches primarily to SEIS-internal stress relaxations caused by the large temperature variations to which the instrument is exposed during a Martian day. Only a small fraction of glitches correspond to a motion of the SEIS package as a whole caused by minuscule tilts of either the instrument or the ground. In this study, we focus on the analysis of the glitch+spike phenomenon and present how these signals can be automatically detected and removed from SEIS's raw data. As glitches affect many standard seismological analysis methods such as receiver functions, spectral decomposition and source inversions, we anticipate that studies of the Martian seismicity as well as studies of Mars' internal structure should benefit from deglitched seismic data. Plain Language Summary The instrument package SEIS (Seismic Experiment for Internal Structure) with two fully equipped seismometers is installed on the surface of Mars as part of NASA's InSight Discovery mission. When compared to terrestrial installations, SEIS is more exposed to wind and daily temperature changes that leads to inevitable degradation of the quality of the recorded data. One consequence is the occurrence of a specific type of transient noise that we term glitch. Glitc

Published

2020

20. New seismological constraints on the crustal structure of Mars and the Moon

Author

Knapmeyer‐Endrun, Brigitte, Panning, Mark P., Bissig, F., Joshi, Rakshit, Khan, A., Kim, Doyeon, Lekic, Vedran, Tauzin, Benoit, Tharimena, S., Plasman, Matthieu, Compaire, Nicolas, Garcia, Raphael F., Margerin, Ludovic, Schimmel, Martin, Stutzmann, E., Schmerr, Nicholas C., Antonangeli, D., Bozdag, E., McLennan, S., Peter, Daniel B., Plesa, A. C., Samuel, H., Wieczorek, M., Davis, Paul, Lognonné, P., Pinot, Baptiste, Scholz, J. R., Staehler, Simon C., Knapmeyer, M., Brinkman, N., van Driel, M., Giardini, Domenico, Johnson, C., Smrekar, S. E., Banerdt, William B., Knapmeyer‐Endrun, Brigitte, Panning, Mark P., Bissig, F., Joshi, Rakshit, Khan, A., Kim, Doyeon, Lekic, Vedran, Tauzin, Benoit, Tharimena, S., Plasman, Matthieu, Compaire, Nicolas, Garcia, Raphael F., Margerin, Ludovic, Schimmel, Martin, Stutzmann, E., Schmerr, Nicholas C., Antonangeli, D., Bozdag, E., McLennan, S., Peter, Daniel B., Plesa, A. C., Samuel, H., Wieczorek, M., Davis, Paul, Lognonné, P., Pinot, Baptiste, Scholz, J. R., Staehler, Simon C., Knapmeyer, M., Brinkman, N., van Driel, M., Giardini, Domenico, Johnson, C., Smrekar, S. E., and Banerdt, William B.

Abstract

Planetary crusts are the results of mantle differentiation, so their thickness provides important constraints on the thermochemical evolution of a planet, including its heat budget and mantle rheology. Information on crustal layering and seismic velocities can also provide important constraints on porosity and geochemistry of the crust. Here, we use data from the InSight mission, which landed in November 2018, to provide seismological constraints on the crustal layering and thickness of Mars for the first time. Results are mainly based on Ps-receiver functions from three events with magnitudes between 3.1 and 3.6 at distances between 27.5° and 47° (±10°) from the lander, originating in the Cerberus Fossae region, the only events, so far, with clear, impulsive P-wave onsets and known epicenter. Ps-receiver functions use converted phases in the P-wave coda to derive information on discontinuities beneath the seismometer. Due to the limited number of events and the small epicentral distance range covered, inversions of the data are still ambiguous. Two sets of models can explain the waveforms, one consisting of a two-layer crust of about 20 to 23 km thickness, the other having a three-layer crust of about 40 to 45 km thickness. By excluding crustal thicknesses in excess of 45 km at the landing site, we can constrain the global average crustal thickness of Mars to be less than 70 km. Both model types also agree with S-receiver functions for two events and seismic P-waves reflected in the crust and extracted from autocorrelations using the coda of different types of marsquakes as well as the background wavefield. Furthermore, the results are compatible with independently conducted moment tensor inversions for a limited number of events as well as modeling of the wave-propagation of high-frequency events. We find low seismic P-wave velocities below 3.4 km/s within the upper approximately 10 km, likely indicating a high porosity. For the Moon, we present Sp-receiver functi

Published

2020

21. Detection, Analysis, and Removal of Glitches From InSight's Seismic Data From Mars

Author

Agence Nationale de la Recherche (France), Swiss Space Office, Schimmel, Martin [0000-0003-2601-4462], Scholz, J. R., Widmer‐Schnidrig, Rudolf, Davis, Paul, Lognonné, P., Pinot, Baptiste, Garcia, Raphael F., Hurst, K., Pou, Laurent, Nimmo, F., Barkaoui, Salma, De Raucourt, Sebastien, Knapmeyer‐Endrun, Brigitte, Knapmeyer, M., Orhand-Mainsant, Guenolé, Compaire, Nicolas, Cuvier, Arthur, Beucler, E., Bonnin, Mickaël, Joshi, Rakshit, Sainton, G., Stutzmann, E., Schimmel, Martin, Horleston, Anna, Böse, M., Ceylan, S., Clinton, John F., van Driel, M., Kawamura, T., Khan, A., Stähler, S. C., Giardini, Domenico, Charalambous, C., Stott, A. E., Pike, William T., Christensen, U., Banerdt, William B., Agence Nationale de la Recherche (France), Swiss Space Office, Schimmel, Martin [0000-0003-2601-4462], Scholz, J. R., Widmer‐Schnidrig, Rudolf, Davis, Paul, Lognonné, P., Pinot, Baptiste, Garcia, Raphael F., Hurst, K., Pou, Laurent, Nimmo, F., Barkaoui, Salma, De Raucourt, Sebastien, Knapmeyer‐Endrun, Brigitte, Knapmeyer, M., Orhand-Mainsant, Guenolé, Compaire, Nicolas, Cuvier, Arthur, Beucler, E., Bonnin, Mickaël, Joshi, Rakshit, Sainton, G., Stutzmann, E., Schimmel, Martin, Horleston, Anna, Böse, M., Ceylan, S., Clinton, John F., van Driel, M., Kawamura, T., Khan, A., Stähler, S. C., Giardini, Domenico, Charalambous, C., Stott, A. E., Pike, William T., Christensen, U., and Banerdt, William B.

Abstract

The instrument package SEIS (Seismic Experiment for Internal Structure) with the three very broadband and three short‐period seismic sensors is installed on the surface on Mars as part of NASA's InSight Discovery mission. When compared to terrestrial installations, SEIS is deployed in a very harsh wind and temperature environment that leads to inevitable degradation of the quality of the recorded data. One ubiquitous artifact in the raw data is an abundance of transient one‐sided pulses often accompanied by high‐frequency spikes. These pulses, which we term “glitches”, can be modeled as the response of the instrument to a step in acceleration, while the spikes can be modeled as the response to a simultaneous step in displacement. We attribute the glitches primarily to SEIS‐internal stress relaxations caused by the large temperature variations to which the instrument is exposed during a Martian day. Only a small fraction of glitches correspond to a motion of the SEIS package as a whole caused by minuscule tilts of either the instrument or the ground. In this study, we focus on the analysis of the glitch+spike phenomenon and present how these signals can be automatically detected and removed from SEIS's raw data. As glitches affect many standard seismological analysis methods such as receiver functions, spectral decomposition and source inversions, we anticipate that studies of the Martian seismicity as well as studies of Mars' internal structure should benefit from deglitched seismic data.

Published

2020

22. First seismic constraints on the Martian crust - receiver functions for InSight

Author

Knapmeyer‐Endrun, Brigitte, Bissig, F., Compaire, Nicolas, García, Raphael, Joshi, Rakshit, Khan, A., Kim, Doyeon, Lekic, Vedran, Margerin, Ludovic, Panning, M., Schimmel, Martin, Schmerr, N., Stutzmann, E., Tauzin, Benoit, Tharimena, S., Stähler, S., Davis, Paul, Pinot, Baptiste, Scholz, J. R., the InSight crustal structure team, Knapmeyer‐Endrun, Brigitte, Bissig, F., Compaire, Nicolas, García, Raphael, Joshi, Rakshit, Khan, A., Kim, Doyeon, Lekic, Vedran, Margerin, Ludovic, Panning, M., Schimmel, Martin, Schmerr, N., Stutzmann, E., Tauzin, Benoit, Tharimena, S., Stähler, S., Davis, Paul, Pinot, Baptiste, Scholz, J. R., and the InSight crustal structure team

Abstract

NASA's InSight mission arrived on Mars in November 2018 and deployed the first very broad-band seismometer, SEIS, on the planet's surface. SEIS has been collecting data continuously since early February 2019, by now recording more than 400 events of different types. InSight aims at enhancing our understanding of the internal structure and dynamics of Mars, including better constraints on its crustal thickness. Various models based on topography and gravity observed from the orbit currently vary in average crustal thickness from 30 km to more than 100 km, with important implications for Mars¿ thermal evolution, and the partitioning of silicates and heat-producing elements between different layers of Mars. We present P-to-S and S-to-P receiver functions, which are available for 4 and 3 marsquakes, respectively, up to now. Out of all of the marsquakes recorded to date, these are the only ones with clear enough P- or S-arrivals not dominated by scattering to make them suitable for the analysis. All of the quakes are located at comparatively small epicentral distances, between 25° and 40°. We observe three consistent phases within the first 10 seconds of the P-to-S receiver functions. The S-to-P receiver functions also show a consistent first phase. Later arrivals are harder to pinpoint, which could be due to the comparatively shallow incidence of the S-waves at the considered distances, which prevents the generation of converted waves. Identification of later multiple phases in the P-to-S receiver functions likewise remains inconclusive. To obtain better constraints on velocity, we also calculated apparent velocity curves from the P-to-S receiver functions, but these provide meaningful results for only one event so far, implying a large uncertainty. Due to difficulties in clearly identifying multiples, the receiver functions can currently be explained by either two crustal layers and a thin (25-30 km) crust or three crustal layers and a thicker (40-45 km) crust at the l

Published

2020

23. SEIS first year: nm/s^2 (and less) broadband seismology on Mars and first steps in Mars-Earth-Moon comparative seismology. (Invited)

Author

Lognonné, P., Banerdt, William B., Pike, William T., Giardini, Domenico, Banfield, D., Christensen, U., Beucler, E., Bierwirth, Marco, Calcutt, Simon B., Daubar, I., Clinton, John F., Kedar, S., Gabsi, T., Garcia, Raphael G., Hurst, K., Kawamura, T., Knapmeyer‐Endrun, Brigitte, Margerin, Ludovic, Mimoun, D., Nimmo, F., Panning, Mark P., De Raucourt, Sebastien, Schmerr, Nicholas C., Smrekar, Suzanne, Spiga, A., Teanby, Nicholas A., Weber, R. C., Wieczorek, M., Zweifel, Peter, Yana, C., Barkaoui, Salma, Brinkman, N., Ceylan, S., Conejero, Vicente, Compaire, Nicolas, Charalambous, C., Davis, Paul, van Driel, M., Drilleau, M., Fayon, Lucile, Kenda, B., Mance, Davor, McClean, John, Murdoch, N., Nebut, Tanguy, Pardo, Constanza, Pinot, Baptiste, Pou, Laurent, Perrin, C., Sainton, G., Sollberger, David, Scholz, J. R., Staehler, Simon C., Roberts, Oliver, Schmelzbach, C., Stott, A., Schimmel, Martin, Stutzmann, E., Tillier, Sylvain, Verdier, Nicolas, Warren, T., Widmer-Schnidrig, Rudolf, Böse, M., Euchner, F., Horleston, Anna C., Khan, A., Orhand-Mainsant, Guenolé, Barrett, E., Gaudin, E., Kerjean, Laurent, Julien, Agnès, Nonon, M., Llorca-Cejudo, R., Laudet, Philippe, Maki, Justin, Mouret, Jean-Marie, Pont, Gabriel, Meunier, Frederic A., Rochas, Ludovic, de Larclause, Isabel Savin, Sylvestre-Baron, Annick, Trebi-Ollenu, Ashitey, Valladeau, J., Delage, P., Jacob, A., Calvet, Marie, Grotte, M., Rodríguez-Manfredi, José Antonio, Lekic, Vedran, Menina, Sabrina, Robertsson, John O.A., Spohn, Tilman, Tauzin, Benoit, Tharimena, S., and Pierick, Jen Ten

Abstract

AGU Fall Meeting 2019 in San Francisco , 9-13 December 2019, EIS/InSIght team, InSight is the first planetary mission with a seismometer package, SEIS, since the Apollo Lunar Surface Experiments Package. SEIS is complimented by APSS, which has as a goal to document the atmospheric source of seismic noise and signals. Since June 2019, SEIS has been delivering 6 axis 20 sps continuous seismic data, a rate one order of magnitude larger originally planned. More than 50 events have been detected by the end of July 2019 but only three have amplitudes significantly above the SEIS instrument requirement. Two have clear and coherent arrivals of P and S waves, enabling location, diffusion/attenuation characterization and receiver function analysis. The event¿s magnitudes are likely ¿ 3 and no clear surface waves nor deep interior phases have been identified. This suggests deep events with scattering along their final propagation paths and with large propagation differences as compared to Earth and Moon quakes. Most of the event¿s detections are made possible due to the very low noise achieved by the instrument installation strategy and the very low VBB self-noise. Most of the SEIS signals have amplitudes of spectral densities in the 0.03-5Hz frequency bandwidth ranging from 10-10 m/s2/Hz1/2 to 5 10-9 m/s2/Hz1/2. The smallest noise levels occurs during the early night, with angstrom displacements or nano-radian tilts. This monitors the elastic and seismic interaction of a planetary surface with its atmosphere, illustrated not only by a wide range of SEIS signals correlated with pressure vortexes, dust devils or wind activity but also by modulation of resonances above 1 Hz, amplified by ultra-low velocity surface layers. After about one half of a Martian year, clear seasonal changes appear also in the noise, which will be discussed. One year after landing, the seismic noise is therefore better and better understood, and noise correction techniques begun to be implemented, either thanks to the APSS wind and pressure sensors, or by SEIS only data processing techniques. These data processing techniques open not only the possibility of better signal to noise ratio of the events, but are also used for various noise auto-correlation techniques as well as searches of long period signals. Noise and seismic signals on Mars are therefore completely different from what seismology encountered previously on Earth and Moon.

Published

2019

24. Detection, Analysis, and Removal of Glitches From InSight's Seismic Data From Mars

Author

Scholz, John‐Robert, primary, Widmer‐Schnidrig, Rudolf, additional, Davis, Paul, additional, Lognonné, Philippe, additional, Pinot, Baptiste, additional, Garcia, Raphaël F., additional, Hurst, Kenneth, additional, Pou, Laurent, additional, Nimmo, Francis, additional, Barkaoui, Salma, additional, de Raucourt, Sébastien, additional, Knapmeyer‐Endrun, Brigitte, additional, Knapmeyer, Martin, additional, Orhand‐Mainsant, Guénolé, additional, Compaire, Nicolas, additional, Cuvier, Arthur, additional, Beucler, Éric, additional, Bonnin, Mickaël, additional, Joshi, Rakshit, additional, Sainton, Grégory, additional, Stutzmann, Eléonore, additional, Schimmel, Martin, additional, Horleston, Anna, additional, Böse, Maren, additional, Ceylan, Savas, additional, Clinton, John, additional, van Driel, Martin, additional, Kawamura, Taichi, additional, Khan, Amir, additional, Stähler, Simon C., additional, Giardini, Domenico, additional, Charalambous, Constantinos, additional, Stott, Alexander E., additional, Pike, William T., additional, Christensen, Ulrich R., additional, and Banerdt, W. Bruce, additional

Published

2020

25. Detection, analysis and removal of glitches from InSight's seismic data from Mars

Author

Scholz, John-Robert, primary, Widmer-Schnidrig, Rudolf, additional, Davis, Paul, additional, Lognonné, Philippe, additional, Pinot, Baptiste, additional, Garcia, Raphaël F, additional, Hurst, Kenneth, additional, Pou, Laurent, additional, Nimmo, Francis, additional, Barkaoui, Salma, additional, De Raucourt, Sébastien, additional, Knapmeyer-Endrun, Brigitte, additional, Knapmeyer, Martin, additional, Mainsant, Guénolé, additional, Compaire, Nicolas, additional, Cuvier, Arthur, additional, Beucler, Eric, additional, Bonnin, Mickaël, additional, Joshi, Rakshit, additional, Sainton, Grégory, additional, Stutzmann, Eléonore, additional, Schimmel, Martin, additional, Horleston, Anna, additional, Böse, Maren, additional, Ceylan, Savas, additional, Clinton, John, additional, Van Driel, Martin, additional, Kawamura, Taichi, additional, Khan, Amir, additional, Stähler, Simon C, additional, Giardini, Domenico, additional, Charalambous, Constantinos, additional, Stott, Alexander E, additional, Pike, William T, additional, Christensen, Ulrich R, additional, and Bruce Banerdt, W, additional

Published

2020

26. Autocorrelation of the ground vibrations recorded by the SEIS-InSight seismometer on Mars

Author

Compaire, Nicolas, primary, Margerin, Ludovic, additional, Garcia, Raphaël F., additional, Pinot, Baptiste, additional, Calvet, Marie, additional, Orhand-Mainsant, Guénolé, additional, Kim, Doyeon, additional, Lekic, Vedran, additional, Tauzin, Benoit, additional, Schimmel, Martin, additional, Stutzmann, Eleonore, additional, Knapmeyer-Endrun, Brigitte, additional, Lognonné, Philippe Henri, additional, Pike, William Thomas, additional, Schmerr, Nicholas Charles, additional, Gizon, Laurent, additional, and Banerdt, William Bruce, additional

Published

2020

27. Detection, analysis and removal of glitches from InSight's 1 seismic data from Mars

Author

Scholz, John-Robert, primary, Widmer-Schnidrig, Rudolf, additional, Davis, Paul, additional, Lognonné, Philippe, additional, Pinot, Baptiste, additional, Garcia, Raphaël F, additional, Nimmo, Francis, additional, Hurst, Kenneth, additional, Barkaoui, Salma, additional, De Raucourt, Sébastien, additional, Pou, Laurent, additional, Mainsant, Guénolé, additional, Compaire, Nicolas, additional, Cuvier, Arthur, additional, Beucler, Eric, additional, Bonnin, Mickaël, additional, Joshi, Rakshit, additional, Stutzmann, Eléonore, additional, Schimmel, Martin, additional, Horleston, Anna, additional, Böse, Maren, additional, Ceylan, Savas, additional, Clinton, John, additional, Van Driel, Martin, additional, Kawamura, Taichi, additional, Khan, Amir, additional, Stähler, Simon C, additional, Giardini, Domenico, additional, Charalambous, Constantinos, additional, Stott, Alexander E, additional, Pike, William T, additional, Christensen, Ulrich R, additional, and Bruce Banerdt, W, additional

Published

2020

28. Detection, Analysis, and Removal of Glitches From InSight's Seismic Data From Mars

Author

L. Pou, Martin Knapmeyer, S. Barkaoui, Taichi Kawamura, Eric Beucler, Amir Khan, Baptiste Pinot, Bruce Banerdt, Rakshit Joshi, Brigitte Knapmeyer-Endrun, John Clinton, Raphaël F. Garcia, Mickael Bonnin, Arthur Cuvier, Grégory Sainton, Constantinos Charalambous, Savas Ceylan, Sebastien de Raucourt, Eléonore Stutzmann, Simon Stähler, John-Robert Scholz, Paul M. Davis, Anna Horleston, Guenolé Orhand-Mainsant, Nicolas Compaire, Francis Nimmo, Ulrich R. Christensen, Martin van Driel, Domenico Giardini, William T. Pike, Martin Schimmel, Maren Böse, Alexander E. Stott, K. Hurst, Rudolf Widmer-Schnidrig, Philippe Lognonné, Agence Nationale de la Recherche (France), Swiss Space Office, Schimmel, Martin [0000-0003-2601-4462], Schimmel, Martin, Widmer‐Schnidrig, Rudolf, 2 Black Forest Observatory, Institute of Geodesy Stuttgart University Stuttgart Germany, Davis, Paul, 3 Department of Earth, Planetary, and Space Sciences University of California Los Angeles Los Angeles CA USA, Lognonné, Philippe, 4 Université de Paris, Institut de physique du globe de Paris, CNRS Paris France, Pinot, Baptiste, 5 Institut Supérieur de l'Aéronautique et de l'Espace SUPAERO Toulouse France, Garcia, Raphaël F., Hurst, Kenneth, 6 Jet Propulsion Laboratory California Institute of Technology Pasadena USA, Pou, Laurent, 7 Department of Earth and Planetary Sciences University of California Santa Cruz Santa Cruz CA USA, Nimmo, Francis, Barkaoui, Salma, de Raucourt, Sébastien, Knapmeyer‐Endrun, Brigitte, 8 Bensberg Observatory University of Cologne Bergisch Gladbach Germany, Knapmeyer, Martin, 9 DLR Institute of Planetary Research Berlin Germany, Orhand‐Mainsant, Guénolé, Compaire, Nicolas, Cuvier, Arthur, 10 Laboratoire de Planétologie et Géodynamique, Université de Nantes, Université d'Angers Nantes France, Beucler, Éric, Bonnin, Mickaël, Joshi, Rakshit, 1 Max Planck Institute for Solar System Research Göttingen Germany, Sainton, Grégory, Stutzmann, Eléonore, 11 Institute of Earth Sciences Jaume Almera ‐ CSIC Barcelona Spain, Horleston, Anna, 12 School of Earth Sciences University of Bristol Bristol UK, Böse, Maren, 13 Swiss Seismological Service (SED) ETH Zurich Zurich, Switzerland, Ceylan, Savas, 14 Institute of Geophysics ETH Zürich Zurich Switzerland, Clinton, John, van Driel, Martin, Kawamura, Taichi, Khan, Amir, Stähler, Simon C., Giardini, Domenico, Charalambous, Constantinos, 16 Department of Electrical and Electronic Engineering Imperial College London London UK, Stott, Alexander E., Pike, William T., Christensen, Ulrich R., Banerdt, W. Bruce, and Institut Supérieur de l'Aéronautique et de l'Espace - ISAE-SUPAERO (FRANCE)

Subjects

Seismometer, 010504 meteorology & atmospheric sciences, lcsh:Astronomy, glitches, seismometer, Mars, Environmental Science (miscellaneous), 010502 geochemistry & geophysics, 01 natural sciences, Glitches, lcsh:QB1-991, Autre, Broadband, 0105 earth and related environmental sciences, InSight, Data processing, removal, lcsh:QE1-996.5, Mars Exploration Program, lcsh:Geology, General Earth and Planetary Sciences, InSight Mars Seismogramme Datenbearbeitung, Mars seismology, Removal, Geology, Seismology, data processing

Abstract

The instrument package SEIS (Seismic Experiment for Internal Structure) with the three very broadband and three short‐period seismic sensors is installed on the surface on Mars as part of NASA's InSight Discovery mission. When compared to terrestrial installations, SEIS is deployed in a very harsh wind and temperature environment that leads to inevitable degradation of the quality of the recorded data. One ubiquitous artifact in the raw data is an abundance of transient one‐sided pulses often accompanied by high‐frequency spikes. These pulses, which we term “glitches”, can be modeled as the response of the instrument to a step in acceleration, while the spikes can be modeled as the response to a simultaneous step in displacement. We attribute the glitches primarily to SEIS‐internal stress relaxations caused by the large temperature variations to which the instrument is exposed during a Martian day. Only a small fraction of glitches correspond to a motion of the SEIS package as a whole caused by minuscule tilts of either the instrument or the ground. In this study, we focus on the analysis of the glitch+spike phenomenon and present how these signals can be automatically detected and removed from SEIS's raw data. As glitches affect many standard seismological analysis methods such as receiver functions, spectral decomposition and source inversions, we anticipate that studies of the Martian seismicity as well as studies of Mars' internal structure should benefit from deglitched seismic data., Plain Language Summary: The instrument package SEIS (Seismic Experiment for Internal Structure) with two fully equipped seismometers is installed on the surface of Mars as part of NASA's InSight Discovery mission. When compared to terrestrial installations, SEIS is more exposed to wind and daily temperature changes that leads to inevitable degradation of the quality of the recorded data. One consequence is the occurrence of a specific type of transient noise that we term “glitch”. Glitches show up in the recorded data as one‐sided pulses and have strong implications for the typical seismic data analysis. Glitches can be understood as step‐like changes in the acceleration sensed by the seismometers. We attribute them primarily to SEIS‐internal stress relaxations caused by the large temperature variations to which the instrument is exposed during a Martian day. Only a small fraction of glitches correspond to a motion of the whole SEIS instrument. In this study, we focus on the detection and removal of glitches and anticipate that studies of the Martian seismicity as well as studies of Mars's internal structure should benefit from deglitched seismic data., Key Points: Glitches due to steps in acceleration significantly complicate seismic records on Mars. Glitches are mostly due to relaxations of thermal stresses and instrument tilt. We provide a toolbox to automatically detect and remove glitches., Centre National d'Etudes Spatiales (CNES), InSight PSP Program, Agence Nationale de la Recherche http://dx.doi.org/10.13039/501100001665, ANR‐19‐CE31‐0008‐08

Published

2020