Links to other bibliographic pages:
Google scholar: https://scholar.google.fr/citations?user=vHFKWOYAAAAJ&hl=en
Orcid: https://orcid.org/0000-0002-3740-9235
[47] A. Walbecq, H. Samuel, A. Limare,
Fully determined three-dimensional velocity field in a divergence-free convection experiment with rigid boundary conditions,
Experiments in Fluids, 65, 70, doi 10.1007/s00348-024-03807-y, 2024
[46] M. Drilleau, H. Samuel, R. Garcia, A. Rivoldini, C. Perrin, M. Wieczorek, P. Lognonné, W. B. Banerdt,
Constraints on Lateral Variations of Martian Crustal Thickness from Seismological and Gravity Field Measurements,
GRL, 51, 4, e2023GL105701, doi 10.1029/2023GL105701, 2024
[45] B Thomas, H. Samuel, C. Farnetani, J. Aubert, C. Chauvel,
Mixing times of heterogeneities in a buoyancy-dominated magma ocean,
GJI, 236, 764-777, doi 10.1093/gji/ggad452, 2023
[44] H. Samuel, M. Drilleau, A. Rivoldini, Z. Xu, Q. Huang, R. F. Garcia, V. Lekic, J.C.E Irving, J. Badro, P. H. Lognonné, J. A. D. Connolly, T. Kawamura, T. Gudkova and W. B. Banerdt,
Geophysical evidence for an enriched molten silicate layer above Mars' core,
Nature, doi : 10.1038/s41586-023-06601-8, 2023 (PDF)
Open access link via: https://www.nature.com/articles/s41586-023-06601-8
[43] Le Maistre S., Rivoldini A., Caldiero A., Yseboodt M., Baland R.-M., Beuthe M., Van Hoolst T., Dehant V., Folkner W. M., Buccino D., Kahan D., Marty J.-C., Antonangeli D., Badro J., Drilleau M., Konopliv A., Péters M. J., Plesa A.-C., Samuel H., Tosi N., Wieczorek M., Lognonné P., Panning M., Smrekar S., Banerdt W. B.,
Spin state and deep interior structure of Mars from InSight radio tracking,
Nature, doi: 10.1038/s41586-023-06150-0, 2023
[42] J. C.E. Irving, V. Lekić , C. Duran, M. Drilleau, D. Kim, A. Rivoldini, A. Khan, H. Samuel, D. Antonangeli, W. B. Banerdt, C. Beghein, E. Bozdağ, S. Ceylan , C. Charalambous, J. Clinton , P. M. Davis, R. Garcia , D. Giardini, A. C. Horleston, Q. Huang, K. J. Hurst , T. Kawamura, S. King, M. Knapmeyer, J. Li, P. Lognonné, R. Maguire, M. Panning , A.-C. Plesa , M. Schimmel, N. C. Schmerr, S. C Stähler, E. Stutzmann, Z. Xu
First observations of core-transiting seismic phases on Mars
PNAS, 120, 18, e2217090120, 2023
[41] A. Salvador, H. Samuel,
Convective outgassing efficiency in planetary magma oceans: insights from computational fluid dynamics
Icarus, doi:10.1016/j.icarus.2022.115265, 2023
[40] C. Durán, A. Khan, S. Ceylan, C. Charalambous, D. Kim, M. Drilleau, H. Samuel, D. Giardini,
Observation of a Core-Diffracted P-Wave From a Farside Impact With Implications for the Lower-Mantle Structure of Mars,
GRL, doi:10.1029/2022GL100887, 2022
[39] D. Kim, W. B. Banerdt, S. Ceylan, D. Giardini, V. Lekic, P. Lognonné, C. Beghein, É. Beucler, S. Carrasco, C. Charalambous, J. Clinton, M. Drilleau, C. Durán, M. Golombek, R. Joshi, A. Khan, B. Knapmeyer-Endrun, J. Li, R. Maguire, W. T. Pike, H. Samuel, M. Schimmel, N. Schmerr, S. C. Stähler, E. Stutzmann, M. Wieczorek, Z. Xu, A. Batov, E. Bozdag, N. Dahmen, P. Davis, T. Gudkova, A. Horleston, Q. Huang, T. Kawamura, S. King, S. M. McLennan, F. Nimmo, M. Plasman, A. C. Plesa, I. E. Stepanova, E. Weidner, G. Zenhäusern, I. J. Daubar, B. Fernando, R. Garcia, L. V. Posiolova, M. P. Panning,
Surface Waves and Crustal Structure on Mars,
Science, 378, doi :10.1126/science.abq7157, 2022
[38] L. Pou, F. Nimmo, A. Rivoldini, A. Khan, A. Bagheri, T. Gray, H. Samuel, P. Lognonné, A.-C. Plesa, T. Gudkova, D. Giardini,
Tidal constraints on the Martian interior,
JGR: Planets, 127, doi:10.1029/2022JE007291, 2022
[37] Q. Huang, N. Schmerr, S. D. King, D. Kim, A. Rivoldini, A.-C. Plesa, H. Samuel, R. Maguire, F. Karakostas, V. Lekić, C. Charalambous, M. Collinet, R. Myhill, D. Antonangeli, M. Drilleau, M. Bystricky,
C. Bollinger, C. Michaut, T. Gudkova, J. Irving, A. Horleston, B. Fernando, K. Leng, T. Nissen-Meyer,
F. Bejina, E. Bozdağ, C. Beghein, L. Waszek, N. Siersch, J.-R. Scholz, P. Davis, P. Lognonné, B. Pinot,
R. Widmer-Schnidrig, M. Panning, S. Smrekar, T. Spohn, W. Pike, D. Giardini, W. B. Banerdt,
Seismic detection of a deep mantle discontinuity within Mars by InSight,
PNAS, 119, e2204474119 doi:10.1073/2022pnas.2204474119, 2022
[36] M. Drilleau, H. Samuel, R. Garcia, A. Rivoldini, C. Perrin, C. Michaut, M. Wieczorek, B. Tauzin,
J. Connolly, P. Meyer, P. Lognonné, W. B. Banerdt,
Marsquake locations and 1-D seismic models for Mars from InSight data,
JGR Planets, doi: 10.1029/2021JE007067, 2022
[35] A. Bagheri, A. Khan, F. Deschamps, H. Samuel, M. Kruglyakov, D. Giardini,
The tidal thermal evolution of the Pluto-Charon system
Icarus, 376, doi:10.1016/j.icarus.2021.114871, 2022
[34] S. Stähler, A. Khan, W. B. Banerdt, P. Lognonné, D. Giardini,
S. Ceylan, M. Drilleau, A. C. Duran, R. Garcia, Q. Huang, D. Kim, V. Lekic, H. Samuel, M. Schimmel,
N. Schmerr, D. Sollberger, É. Stutzmann, Z. Xu, D. Antonangeli, C. Charalambous, P. Davis, J. Irving,
T. Kawamura, M. Knapmeyer, R. Maguire, A. Marusiak, M. Panning, C. Perrin, A.-C. Plesa, A. Rivoldini,
C. Schmelzbach, G. Zenhäusern, É. Beucler, J. Clinton, N. Dahmen, M. van Driel, T. G., A. Horleston,
T. Pike, M. Plasman, S. Smrekar
Seismic detection of the Martian core
Science, 373, 443-448, 2021
[33] B. Knapmeyer-Endrun, M. Panning, F. Bissig, R. Joshi, A. Khan, D. Kim, V. Lekic, B. Tauzin,
S. Tharimena, M. Plasman, N. Compaire, R. Garcia, L. Margerin, M. Schimmel, É. Stutzmann, N. Schmerr,
E. Bozdag, A.-C. Plesa, M. Wieczorek, A. Broquet, D. Antonangeli, S. McLennan, H. Samuel, C. Michaut,
L. Pan, S. Smrekar, C. Johnson, N. Brinkman, A. Mittelholz, A. Rivoldini, P. Davis, P. Lognonné, B. Pinot,
J.-R. Scholz, S. Stähler, M. Knapmeyer, M. van Driel, D. Giardini, W. B. Banerdt
Thickness and structure of the martian crust from InSight seismic data
Science, 373, 438-443, 2021
[32] A. Khan, S. Ceylan, M. van Driel, D. Giardini, P. Lognonné, H. Samuel, N. Schmerr, S. Stähler,
C. Duran, Q. Huang, D. Kim, A. Broquet, C. Charalambous, J. F. Clinton, P. Davis, M. Drilleau,
F. Karakostas, V. Lekic, S. M. McLennan, R. Maguire, C. Michaut, M. Panning, W. Pike, B. Pinot,
M. Plasman, J.-R. Scholz, R. Widmer-Schnidrig, T. Spohn, S. Smrekar, W. B. Banerdt
Upper mantle structure of Mars from InSight seismic data
Science, 373, 434-438, 2021
[31] M. Drilleau, H. Samuel, A. Rivoldini, M. Panning, P. Lognonné,
Bayesian inversion of the Martian structure using geodynamic constraints
Geophys. Journal International, 226, 1615-1644, doi:10.1093/gji/ggab105, 2021 (PDF)
[30] H. Samuel, M. Ballmer, S. Padovan, N. Tosi, A. Rivoldini, A-C. Plesa,
The thermo-chemical evolution of Mars with a strongly stratified mantle
J. Geophys. Res. Planets, 126, doi:10.1029/2020JE006613, 2021 (PDF)
[29] J. Magali, T. Bodin, N. Hedjazian, H. Samuel , S. Atkins
Geodynamic Tomography: constraining upper mantle deformation patters from Bayesian inversion of
surface waves
Geophys. Journal International, 224, 2077-2099, doi 10.1093/gji/ggaa577, 2020 (PDF)
[28] M. Drilleau, É. Beucler, P. Lognonné, M. Panning, B. Knapmeyer‐Endrun, W. Bruce Banerdt,
C. Beghein, S. Ceylan, M. van Driel, R. Joshi, T. Kawamura, A. Khan, S. Menina, A. Rivoldini,
H. Samuel, S. Stähler, H. Xu, M. Bonnin, J. Clinton, D. Giardini, B. Kenda, V. Lekic, A. Mocquet,
N. Murdoch, M. Schimmel, S. E. Smrekar, É. Stutzmann, B. Tauzin, S. Tharimena
MSS/1: Single-station and single-event marsquake inversion
doi:10.1029/2020EA001118, Earth and Space Science, 7, 2020 (PDF)
[27] D. Giardini, P. Lognonné, W. Banerdt, W. Pike, U. Christensen, S. Ceylan, J. Clinton,
M. van Driel, S. Stähler, M. Böse, R. Garcia, A. Khan, M. Panning, C. Perrin, D. Banfield,
E. Beucler, C. Charalambous, F. Euchner, A. Horleston, A. Jacob, T. Kawamura, S. Kedar,
G. Mainsant, J.-R. Scholz, S. Smrekar, A. Spiga, C. Agard, D. Antonangeli, S. Barkaoui, E. Barrett,
P. Combes, V. Conejero, I. Daubar, M. Drilleau, C. Ferrier, T. Gabsi, T. Gudkova,
K.Hurst, F. Karakostas, S. King, M. Knapmeyer, B. Knapmeyer-Endrun, R. Ljorca-Cejudo,
A. Lucas, L. Luno, M. Margerin, J. McClean, D. Mimoun, N. Murdoch, F. Nimmo, M. Nonon,
C. Pardo, A. and Rivoldini, J. Manfredi, J. A. Rodriguez, H. Samuel, M. Schimmel, A. E. Stott,
E. Stutzman, N. Teanby, T. Warren, R. Weber, M. Wieczorek, C. Yana.
The seismicity of Mars
Nature Geoscience, 13, 205-212, 2020 (PDF)
[26] J. Monteux, D. Andrault, Guitreau, M., H. Samuel , S. Demouchy
A mushy Earth’s mantle for more than 500 Myr after the magma ocean solidification
Geophys. Journal International, 221, 1165-1181, 2020 (PDF)
[25] H. Samuel , P. Lognonné, M. Panning, V. Lainey
The rheology and thermal history of Mars revealed by the orbital evolution of Phobos
Nature, 569, 523-527, doi: 10.1038/s41586-019-1202-7, 2019
[24] S. E. Smrekar, P. Lognonné, T. Spohn, W. Bruce Banerdt, D. Breuer, U. Christensen, V. Dehant,
M. Drilleau, W. Folkner, N. Fuji, R. F. Garcia, D. Giardini, M. Golombek, M. Grott, T. Gudkova, C. Johnson,
A. Khan, B. Langlais, A. Mittelholz, A. Mocquet, R. Myhill, M. Panning, C. Perrin, T. Pike, A.-C. Plesa,
A. Rivoldini, H. Samuel, S. C. Stähler, M. van Driel, T. Van Hoolst, O. Verhoeven, R. Weber, M. Wieczorek,
Pre-mission InSights on the Interior of Mars
Space Sci. Rev., 215, doi: 10.1007/s11214-018-0563-9 , 2019 (PDF)
[23] H. Samuel,
A Deformable Particle-In-Cell Method for Advective Transport in Geodynamic Modelling
Geophys. Journal International, 214, 1744-1773, 2018 (PDF)
[22] M. Maurice, N. Tosi, H. Samuel, A.-C. Plesa, C. Huettig, D. Breuer,
Onset of solid-state convection and mixing during magma ocean solidification
J.Geophys. Res. Planets, doi:10.1002/2016JE005250, 2017 (PDF)
(See also JGR highlights and cover for March 2017)
[21] J. Monteux, D. Andrault, H. Samuel,
On the Cooling of a Deep Terrestrial Magma Ocean
Earth Planet. Sci. Lett., 448, 140-149, 2016 (PDF)
[20] D. Andrault, J. Monteux, M. LeBars, H. Samuel,
The deep Earth may not be cooling down
Earth Planet. Sci. Lett., 443, 195-203, 2016 (PDF)
[19] N. Tosi, C. Stein, L. Noack, C. Huettig, P. Maierova, H. Samuel, R. Davies, C. R. Wilson, S.C. Kramer,
C. Thieulot, A. Glerum, M. Fraters, W. Spakman, A. Rozel, P. J. Tackley,
A community benchmark for viscoplastic thermal convection in a 2-D squared box
G-cubed, 16, doi:0.1002/2015GC005807, 2015 (PDF)
[18] H. Samuel, S. D. King
Mixing at mid-ocean ridges controlled by small-scale convection and plate motion
Nature Geoscience, 7, 602-605, doi:10.1038/ngeo2208, 2014 (PDF) (supplementary_info)
(See also News & Views by D. Graham)
[17] D. Baratoux, H. Samuel, C. Michaut, M. J. Toplis, M. Monnereau, M. Wieczorek, R. Garcia,
K. Kurita, Petrological constraints on the density of the Martian crust,
J. Geophys. Res. Planets, 119, 1707-1727, doi:10.1002/2014JE004642, 2014 (PDF)
[16] H. Samuel,
A Level Set Two-way Wave Equation Approach for Eulerian Interface Tracking,
J. Comput. Phys., 259, 617-635, 2014 (PDF)
[15] R. Morishima, G. Golabek, H. Samuel,
N-body simulations of oligarchic growth of Mars: Implications for Hf-W chronology,
Earth Planet. Sci. Lett., 366, 6-16, 2013 (PDF)
[14] H. Samuel, & N. Tosi,
The influence of post-perovskite strength on the Earth’s mantle thermal & chemical evolution,
Earth Planet. Sci. Lett., 323-324, 50-59, 2012 (PDF)
[13] M. Evonuk & H. Samuel,
Simulating rotating fluid bodies: When is vorticity generation via density-stratification important?
Earth Planet. Sci. Lett., 317-318, 1-7, 2012 (PDF)
[12] H. Samuel,
Time-domain parallelization for computational geodynamics
G-cubed, 13, doi:10.1029/2011GC003905, 2012 (PDF)
[11] H. Samuel,
A re-evaluation of metal diapir breakup and equilibration in terrestrial magma oceans
Earth Planet. Sci. Lett., 313-314, 105-114, 2012 (PDF)
[10] O. Narygina, L. S. Dubrovinsky, H. Samuel, C. A. McCammon, I. Y. Kantor, K. Glazyrin, S. Pascarelli,
G. Aquilanti, V. B. Prakapenka
Chemically homogeneous spin transition zone in Earth's lower mantle,
Phys. Planet. Sci. Lett., 185, 107-111, 2011
[9] H. Samuel, V. Aleksandrov, B. Deo
The effect of continents on mantle convective stirring,
Geophys. Res. Lett., 38, L04307, doi:10.1029/2010GL046056, 2011 (PDF)
[8] H. Samuel, M. Evonuk,
Modeling Advection in Geophysical Flows with Particle Level Sets,
G-cubed, 11, Q08020, doi:10.1029/2010GC003081, 2010 (PDF)
[7] H. Samuel, P. J. Tackley, M. Evonuk,
Heat Partitioning in Terrestrial Planets During Core Formation by Negative Diapirism,
Earth Planet. Sci. Lett., 290, 13-19, 2010 (PDF)
[6] H. Samuel & P. J. Tackley,
Dynamics of core formation and equilibration by negative diapirism,
G-cubed, 2008 (PDF)
[5] H. Samuel & D. Bercovici,
Oscillating and stagnating plumes in the Earth’s lower mantle,
Earth Planet. Sci. Lett., 2006 (PDF)
[4] H. Samuel , C. G. Farnetani and D. Andrault,
Heterogeneous lowermost mantle: compositional constraints and seismological observables,
AGU Geophysical Monograph: Structure Evolution and Composition of the Earth's Mantle, J. Bass,
R. D. van der Hilst, J. Matas, J. Trampert eds., 2005 (PDF)
[3] C. G. Farnetani & H. Samuel,
Beyond the thermal plume paradigm,
Geophys. Res. Lett., 32, No.7,L07311, 10.1029/2005GL022360, 2005. (PDF)
[2] H. Samuel & C. G. Farnetani
Thermochemical convection and helium concentrations in mantle plumes,
Earth Planet. Sci. Lett., 207, 39-56, 2003. (PDF)
[1] C. G. Farnetani & H. Samuel,
Lagrangian structures and stirring in the Earth's Mantle,
Earth Planet. Sci. Lett., 206, 335-348, 2003. (PDF)