Your search keyword '"Rajšić, Andrea"' showing total 13 results

1. Newly formed craters on Mars located using seismic and acoustic wave data from InSight

Author

Garcia, Raphael F., Daubar, Ingrid J., Beucler, Éric, Posiolova, Liliya V., Collins, Gareth S., Lognonné, Philippe, Rolland, Lucie, Xu, Zongbo, Wójcicka, Natalia, Spiga, Aymeric, Fernando, Benjamin, Speth, Gunnar, Martire, Léo, Rajšić, Andrea, Miljković, Katarina, Sansom, Eleanor K., Charalambous, Constantinos, Ceylan, Savas, Menina, Sabrina, Margerin, Ludovic, Lapeyre, Rémi, Neidhart, Tanja, Teanby, Nicholas A., Schmerr, Nicholas C., Bonnin, Mickaël, Froment, Marouchka, Clinton, John F., Karatekin, Ozgur, Stähler, Simon C., Dahmen, Nikolaj L., Durán, Cecilia, Horleston, Anna, Kawamura, Taichi, Plasman, Matthieu, Zenhäusern, Géraldine, Giardini, Domenico, Panning, Mark, Malin, Mike, and Banerdt, William Bruce

Published

2022

2. Deep Learning driven interpretation of Chang'E4 Lunar Penetrating Radar

Author

RONCORONI, Giacomo, primary, Forte, Emanuele, additional, Santin, Ilaria, additional, Černok, Ana, additional, Rajšić, Andrea, additional, Frigeri, Alessandro, additional, zhao, wenke, additional, and Pipan, Michele, additional

Published

2023

3. Newly formed craters on Mars located using seismic and acoustic wave data from InSight

Author

Garcia, R.F., Daubar, I.J., Beucler, É., Posiolova, L.V., Collins, G.S., Lognonné, P., Rolland, L., Xu, Z., Wójcicka, N., Spiga, A., Fernando, B., Speth, G., Martire, L., Rajšić, Andrea, Miljković, Katarina, Sansom, Eleanor, Charalambous, C., Ceylan, S., Menina, S., Margerin, L., Lapeyre, R., Neidhart, Tanja, Teanby, N.A., Schmerr, N.C., Bonnin, M., Froment, M., Clinton, J.F., Karatekin, O., Stähler, S.C., Dahmen, N.L., Durán, C., Horleston, A., Kawamura, T., Plasman, M., Zenhäusern, G., Giardini, D., Panning, M., Malin, M., Banerdt, W.B., Garcia, R.F., Daubar, I.J., Beucler, É., Posiolova, L.V., Collins, G.S., Lognonné, P., Rolland, L., Xu, Z., Wójcicka, N., Spiga, A., Fernando, B., Speth, G., Martire, L., Rajšić, Andrea, Miljković, Katarina, Sansom, Eleanor, Charalambous, C., Ceylan, S., Menina, S., Margerin, L., Lapeyre, R., Neidhart, Tanja, Teanby, N.A., Schmerr, N.C., Bonnin, M., Froment, M., Clinton, J.F., Karatekin, O., Stähler, S.C., Dahmen, N.L., Durán, C., Horleston, A., Kawamura, T., Plasman, M., Zenhäusern, G., Giardini, D., Panning, M., Malin, M., and Banerdt, W.B.

Abstract

Meteoroid impacts shape planetary surfaces by forming new craters and alter atmospheric composition. During atmospheric entry and impact on the ground, meteoroids excite transient acoustic and seismic waves. However, new crater formation and the associated impact-induced mechanical waves have yet to be observed jointly beyond Earth. Here we report observations of seismic and acoustic waves from the NASA InSight lander’s seismometer that we link to four meteoroid impact events on Mars observed in spacecraft imagery. We analysed arrival times and polarization of seismic and acoustic waves to estimate impact locations, which were subsequently confirmed by orbital imaging of the associated craters. Crater dimensions and estimates of meteoroid trajectories are consistent with waveform modelling of the recorded seismograms. With identified seismic sources, the seismic waves can be used to constrain the structure of the Martian interior, corroborating previous crustal structure models, and constrain scaling relationships between the distance and amplitude of impact-generated seismic waves on Mars, supporting a link between the seismic moment of impacts and the vertical impactor momentum. Our findings demonstrate the capability of planetary seismology to identify impact-generated seismic sources and constrain both impact processes and planetary interiors.

Published

2022

4. Largest recent impact craters on Mars: Orbital imaging and surface seismic co-investigation

Author

Posiolova, L.V., Lognonné, P., Banerdt, W.B., Clinton, J., Collins, G.S., Kawamura, T., Ceylan, S., Daubar, I.J., Fernando, B., Froment, M., Giardini, D., Malin, M.C., Miljković, Katarina, Stähler, S.C., Xu, Z., Banks, M.E., Beucler, Cantor, B.A., Charalambous, C., Dahmen, N., Davis, P., Drilleau, M., Dundas, C.M., Durán, C., Euchner, F., Garcia, R.F., Golombek, M., Horleston, A., Keegan, C., Khan, A., Kim, D., Larmat, C., Lorenz, R., Margerin, L., Menina, S., Panning, M., Pardo, C., Perrin, C., Pike, W.T., Plasman, M., Rajšić, Andrea, Rolland, L., Rougier, E., Speth, G., Spiga, A., Stott, A., Susko, D., Teanby, N.A., Valeh, A., Werynski, A., Wójcicka, N., Zenhäusern, G., Posiolova, L.V., Lognonné, P., Banerdt, W.B., Clinton, J., Collins, G.S., Kawamura, T., Ceylan, S., Daubar, I.J., Fernando, B., Froment, M., Giardini, D., Malin, M.C., Miljković, Katarina, Stähler, S.C., Xu, Z., Banks, M.E., Beucler, Cantor, B.A., Charalambous, C., Dahmen, N., Davis, P., Drilleau, M., Dundas, C.M., Durán, C., Euchner, F., Garcia, R.F., Golombek, M., Horleston, A., Keegan, C., Khan, A., Kim, D., Larmat, C., Lorenz, R., Margerin, L., Menina, S., Panning, M., Pardo, C., Perrin, C., Pike, W.T., Plasman, M., Rajšić, Andrea, Rolland, L., Rougier, E., Speth, G., Spiga, A., Stott, A., Susko, D., Teanby, N.A., Valeh, A., Werynski, A., Wójcicka, N., and Zenhäusern, G.

Abstract

Two >130-meter-diameter impact craters formed on Mars during the later half of 2021. These are the two largest fresh impact craters discovered by the Mars Reconnaissance Orbiter since operations started 16 years ago. The impacts created two of the largest seismic events (magnitudes greater than 4) recorded by InSight during its 3-year mission. The combination of orbital imagery and seismic ground motion enables the investigation of subsurface and atmospheric energy partitioning of the impact process on a planet with a thin atmosphere and the first direct test of martian deep-interior seismic models with known event distances. The impact at 35°N excavated blocks of water ice, which is the lowest latitude at which ice has been directly observed on Mars.

Published

2022

5. Early crustal processes revealed by the ejection site of the oldest martian meteorite

Author

Lagain, Anthony, Bouley, S., Zanda, B., Miljković, Katarina, Rajšić, Andrea, Baratoux, D., Payré, V., Doucet, Luc, Timms, Nick, Hewins, R., Benedix, Gretchen, Malarewic, V., Servis, Konstantinos, Bland, Phil, Lagain, Anthony, Bouley, S., Zanda, B., Miljković, Katarina, Rajšić, Andrea, Baratoux, D., Payré, V., Doucet, Luc, Timms, Nick, Hewins, R., Benedix, Gretchen, Malarewic, V., Servis, Konstantinos, and Bland, Phil

Abstract

The formation and differentiation of the crust of Mars in the first tens of millions of years after its accretion can only be deciphered from incredibly limited records. The martian breccia NWA 7034 and its paired stones is one of them. This meteorite contains the oldest martian igneous material ever dated: ~4.5 Ga old. However, its source and geological context have so far remained unknown. Here, we show that the meteorite was ejected 5–10 Ma ago from the north-east of the Terra Cimmeria—Sirenum province, in the southern hemisphere of Mars. More specifically, the breccia belongs to the ejecta deposits of the Khujirt crater formed 1.5 Ga ago, and it was ejected as a result of the formation of the Karratha crater 5–10 Ma ago. Our findings demonstrate that the Terra Cimmeria—Sirenum province is a relic of the differentiated primordial martian crust, formed shortly after the accretion of the planet, and that it constitutes a unique record of early crustal processes. This province is an ideal landing site for future missions aiming to unravel the first tens of millions of years of the history of Mars and, by extension, of all terrestrial planets, including the Earth.

Published

2022

6. Numerical modelling of the artificial impacts on the Moon

Author

Rajšić, Andrea, primary, Miljković, Katarina, additional, Wojcicka, Natalia, additional, Onodera, Keisuke, additional, Collins, Gareth, additional, Kawamura, Taichi, additional, Lognonne, Philipe, additional, Wieczorek, Mark, additional, and Daubar, Ingrid, additional

Published

2021

7. Seismic Efficiency for Simple Crater Formation in the Martian Top Crust Analog

Author

Rajšić, Andrea, Miljkovic, Katarina, Collins, G.S., Wünnemann, K., Daubar, I.J., Wójcicka, N., Wieczorek, M.A., Rajšić, Andrea, Miljkovic, Katarina, Collins, G.S., Wünnemann, K., Daubar, I.J., Wójcicka, N., and Wieczorek, M.A.

Abstract

The first seismometer operating on the surface of another planet was deployed by the NASA InSight (Interior Exploration using Seismic Investigations, Geodesy and Heat Transport) mission to Mars. It gives us an opportunity to investigate the seismicity of Mars, including any seismic activity caused by small meteorite bombardment. Detectability of impact generated seismic signals is closely related to the seismic efficiency, defined as the fraction of the impactor's kinetic energy transferred into the seismic energy in a target medium. This work investigated the seismic efficiency of the Martian near surface associated with small meteorite impacts on Mars. We used the iSALE-2D (Impact-Simplified Arbitrary Lagrangian Eulerian) shock physics code to simulate the formation of the meter-size impact craters, and we used a recently formed 1.5 m diameter crater as a case study. The Martian crust was simulated as unfractured nonporous bedrock, fractured bedrock with 25% porosity, and highly porous regolith with 44% and 65% porosity. We used appropriate strength and porosity models defined in previous works, and we identified that the seismic efficiency is very sensitive to the speed of sound and elastic threshold in the target medium. We constrained the value of the impact-related seismic efficiency to be between the order of ∼10-7 to 10-6 for the regolith and ∼10-4 to 10-3 for the bedrock. For new impacts occurring on Mars, this work can help understand the near-surface properties of the Martian crust, and it contributes to the understanding of impact detectability via seismic signals as a function of the target media.

Published

2021

8. Numerical Simulations of the Apollo S-IVB Artificial Impacts on the Moon

Author

Rajšić, Andrea, Miljkovic, Katarina, Wójcicka, N., Collins, G.S., Onodera, K., Kawamura, T., Lognonné, P., Wieczorek, M.A., Daubar, I.J., Rajšić, Andrea, Miljkovic, Katarina, Wójcicka, N., Collins, G.S., Onodera, K., Kawamura, T., Lognonné, P., Wieczorek, M.A., and Daubar, I.J.

Abstract

The third stage of the Saturn IV rocket used in the five Apollo missions made craters on the Moon ∼30 m in diameter. Their initial impact conditions were known, so they can be considered controlled impacts. Here, we used the iSALE-2D shock physics code to numerically simulate the formation of these craters, and to calculate the vertical component of seismic moment (∼4 × 1010 Nm) and seismic efficiency (∼10−6) associated with these impacts. The irregular booster shape likely caused the irregular crater morphology observed. To investigate this, we modeled six projectile geometries, with footprint area between 3 and 105 m2, keeping the mass and velocity of the impactor constant. We showed that the crater depth and diameter decreased as the footprint area increased. The central mound observed in lunar impact sites could be a result of layering of the target and/or low density of the projectile. Understanding seismic signatures from impact events is important for planetary seismology. Calculating seismic parameters and validating them against controlled experiments in a planetary setting will help us understand the seismic data received, not only from the Moon, but also from the InSight Mission on Mars and future seismic missions.

Published

2021

9. Numerical modeling of small impacts on Mars

Author

Anthony Lagain, Rajšić, Andrea, Anthony Lagain, and Rajšić, Andrea

Abstract

The NASA InSight mission placed a seismometer on the surface of Mars in 2019. Since then, several hundred seismic signatures have been recorded. I am collaborating with the NASA InSight science team dedicated to understanding small meteorite impacts occurring on Mars. Such small impacts majorly form in the uppermost crust of Mars, which has focused my thesis research on understanding the properties of the uppermost crust of Mars and connecting these with impact-induced seismic properties.

Published

2021

10. Complex Crater Collapse: A Comparison of the Block and Melosh Acoustic Fluidization Models of Transient Target Weakening

Author

Hay, Hamish C. F. C., Collins, Gareth S., Davison, Thomas M., Rajšić, Andrea, and Johnson, Brandon C.

Abstract

The collapse of large impact craters requires a temporary reduction in the resistance to shear deformation of the target rocks. One explanation for such weakening is acoustic fluidization, where impact‐generated pressure fluctuations temporarily and locally relieve overburden pressure facilitating slip. A model of acoustic fluidization widely used in numerical impact simulations is the Block model. Simulations employing the Block model have successfully reproduced large‐scale crater morphometry and structural deformation but fail to predict localized weakening in the rim area and require unrealistically long pressure fluctuation decay times. Here, we modify the iSALE shock physics code to implement an alternative model of acoustic fluidization, which we call the Melosh model, that accounts for regeneration and scattering of acoustic vibrations not considered by the Block model. The Melosh model of acoustic fluidization is shown to be an effective model of dynamic weakening, differing from the Block model in the style of crater collapse and peak ring formation that it promotes. While the Block model facilitates complex crater collapse by weakening rocks deep beneath the crater, the Melosh model results in shallower and more localized weakening. Inclusion of acoustic energy regeneration in the Melosh model reconciles required acoustic energy dissipation rates with those typically derived from crustal seismic wave propagation analysis. Large “complex” impact craters differ in appearance from their smaller, bowl‐shaped counterparts. They are shallower in aspect, with terraced rim walls and an uplifted central mountainous peak or ring of mountains. These differences are the result of dramatic collapse of an initially bowl‐shaped cavity, which only happens in large craters, and is facilitated by temporary weakening of the target rocks. The physical mechanism for this weakening, however, is still debated. One potential weakening mechanism is acoustic fluidization: where impact‐generated vibrations around the crater reduce resistance to deformation until the vibrations dissipate. Computer simulations of large crater collapse that employ this idea have successfully reproduced many observations of large craters on rocky and icy planetary bodies. However, those simulations are yet to replicate rock fracturing in the crater rim region and require that the vibrations persist for much longer than is typical for analogous vibrations produced by earthquakes. By implementing an alternative model of acoustic fluidization we show that the regeneration of vibrations during crater formation facilitates more localized deformation during collapse and explains how vibrations can be sustained around the crater for such a long time. This paves the way for more realistic simulations of crater formation in the future. Acoustic fluidization is a mechanism to explain temporary weakening of target rocks during the collapse of large impact structuresThe Melosh model of acoustic fluidization that accounts for scattering and regeneration of acoustic energy is implemented in the iSALE codeRegeneration of acoustic energy facilitates localized deformation and sustains vibrations for the duration of crater collapse Acoustic fluidization is a mechanism to explain temporary weakening of target rocks during the collapse of large impact structures The Melosh model of acoustic fluidization that accounts for scattering and regeneration of acoustic energy is implemented in the iSALE code Regeneration of acoustic energy facilitates localized deformation and sustains vibrations for the duration of crater collapse

Published

2024

11. The Seismic Moment and Seismic Efficiency of Small Impacts on Mars

Author

Wójcicka, N., Collins, G.S., Bastow, I.D., Teanby, N.A., Miljkovic, Katarina, Rajšić, Andrea, Daubar, I., Lognonné, P., Wójcicka, N., Collins, G.S., Bastow, I.D., Teanby, N.A., Miljkovic, Katarina, Rajšić, Andrea, Daubar, I., and Lognonné, P.

Abstract

Since landing in late 2018, the InSight lander has been recording seismic signals on the surface of Mars. Despite nominal prelanding estimates of one to three meteorite impacts detected per Earth year, none have yet been identified seismically. To inform revised detectability estimates, we simulated numerically a suite of small impacts onto Martian regolith and characterized their seismic source properties. For the impactor size and velocity range most relevant for InSight, crater diameters are 1–30 m. We found that in this range scalar seismic moment is 106–1010 Nm and increases almost linearly with impact momentum. The ratio of horizontal to vertical seismic moment tensor components is ∼1, implying an almost isotropic P wave source, for vertical impacts. Seismic efficiencies are ∼10−6, dependent on the target crushing strength and impact velocity. Our predictions of relatively low seismic efficiency and seismic moment suggest that meteorite impact detectability on Mars is lower than previously assumed. Detection chances are best for impacts forming craters of diameter >10 m.

Published

2020

12. Mikrotektonska istraživanja istočnih padina Miroča – preliminarni rezultati

Author

Rajšić, Andrea, Radonjić, M, Balen, Dražen, Gerzina Spajić, Nataša, Ganić, Meri, Cvetkov, Vesna, Vulić, Predrag, Đurić, Dragana, and Đurić, Uroš

Subjects

mikrotektonika, metamorfne stijene, Miroč

Abstract

U radu se prezentiraju rezultati koji su dijelom dobiveni u okviru CEEEPUS mreže gje je putem studentske razmjene kolegica Rajšić pohađala kolegije vezena uz mikrotektonsku analizu h stijena istočnih padina Miroča. Tom prilikom su utvrđene mikrostrukturne značajke kiselih magmatskih stijena te metamorfnih stijena i okvirno određeni P-T uvjeti.

Published

2018

13. Complex Crater Collapse: A Comparison of the Block and Melosh Acoustic Fluidization Models of Transient Target Weakening.

Author

Hay HCFC, Collins GS, Davison TM, Rajšić A, and Johnson BC

Abstract

The collapse of large impact craters requires a temporary reduction in the resistance to shear deformation of the target rocks. One explanation for such weakening is acoustic fluidization, where impact-generated pressure fluctuations temporarily and locally relieve overburden pressure facilitating slip. A model of acoustic fluidization widely used in numerical impact simulations is the Block model. Simulations employing the Block model have successfully reproduced large-scale crater morphometry and structural deformation but fail to predict localized weakening in the rim area and require unrealistically long pressure fluctuation decay times. Here, we modify the iSALE shock physics code to implement an alternative model of acoustic fluidization, which we call the Melosh model, that accounts for regeneration and scattering of acoustic vibrations not considered by the Block model. The Melosh model of acoustic fluidization is shown to be an effective model of dynamic weakening, differing from the Block model in the style of crater collapse and peak ring formation that it promotes. While the Block model facilitates complex crater collapse by weakening rocks deep beneath the crater, the Melosh model results in shallower and more localized weakening. Inclusion of acoustic energy regeneration in the Melosh model reconciles required acoustic energy dissipation rates with those typically derived from crustal seismic wave propagation analysis., (© 2024. The Author(s).)

Published

2024