Planet Formation and Evolution

1. Reduced atmospheres of post-impact worlds: The early Earth
   Itcovitz, J. P., A. S. P. Rae, R. I. Citron, S. T. Stewart, C. A. Sinclair, P. B. Rimmer, and O. Shorttle, The Planetary Science Journal 3, 116 (23pp), doi:10.3847/PSJ/ac67a9, 2022.
2. Did Earth eat its leftovers? Impact ejecta as a component of the late veneer
   Carter, P.J., S.T. Stewart, The Planetary Science Journal 3, 83, doi:10.3847/PSJ/ac6095, 2022.
3. Large Impacts onto the Early Earth: Planetary Sterilization and Iron Delivery
   Citron, R.I., S.T. Stewart, The Planetary Science Journal 3, 115 (23pp), doi:10.3847/PSJ/ac66e8, 2022.
4. New Perspectives on the Exoplanet Radius Gap from a Mathematica Tool and Visualized Water Equation of State
   Zeng, L., S. B. Jacobsen, E. Hyung, A. Levi, C. Nava, J. Kirk, C. Piaulet, G. Lacedelli, D. D. Sasselov, M. I. Petaev, S. T. Stewart, M. K. Alam, M. López-Morales, M. Damasso, D. W. Latham, Astrophysical Journal 923, 247, doi:10.3847/1538-4357/ac3137, 2021.
5. Tidal Evolution of the Earth-Moon System with a High Initial Obliquity
   Ćuk, M., S. J. Lock, S. T. Stewart, D. P. Hamilton, The Planetary Science Journal 2, 147, doi:10.3847/PSJ/ac12d1, 2021.
6. Colliding in the shadows of giants: Planetesimal collisions during the growth and migration of gas giants
   Carter, P. J., S. T. Stewart, The Planetary Science Journal 1, doi:10.3847/PSJ/abaecc, 2020. (arXiv:2008.05549)
7. The energy budgets of giant impacts
   Carter, P. J., S. J. Lock, S. T. Stewart, J. Geophysical Research: Planets 125, e2019JE006042, doi:10.1029/2019JE006042, 2020.
8. Early Dynamics of the Lunar Core
   Ćuk, M., D. P. Hamilton, S. T. Stewart, J. Geophysical Research: Planets 124, 2917-2928, doi:10.1029/2019JE006016, 2019.
9. The energy budget and figure of Earth during recovery from the Moon-Forming giant impact
   Lock, S. J., S. T. Stewart, M. Ćuk, Earth and Planetary Science Letters, 530, 115885, doi:10.1016/j.epsl.2019.115885, 2019.
10. Giant impacts stochastically change the internal pressures of terrestrial planets
    Lock, S. J., S. T. Stewart, Science Advances, 5, eaav3746, doi: 10.1126/sciadv.aav3746, 2019.
11. The Origin of the Moon from a Terrestrial Synestia
    Lock, S. J., S. T. Stewart, M. I. Petaev, Z. M. Leinhardt, M. Mace, S. B. Jacobsen, and M. Ćuk, J. Geophysical Research: Planets 123, 910-951, doi:10.1002/2017JE005333, 2018. (arXiv:1802.10223)
12. Collisional stripping of planetary crusts
    Carter, P. J., Z. M. Leinhardt, T. Elliott, S. T. Stewart, M. J. Walter, Earth and Planetary Science Letters 484, 276-286, doi:10.1016/j.epsl.2017.12.012, 2018. (arXiv:1712.02790)
13. The structure of terrestrial bodies: Impact heating, corotation limits and synestias
    Lock, S. J., and S. T. Stewart, J. Geophysical Research: Planets, 122, 950-982, doi:10.1002/2016JE005239, 2017. (arXiv:1705.07858)
14. The Elusive Origin of Mercury
    Ebel, D. S., S. T. Stewart. In Mercury: The View after MESSENGER, Cambridge University Press, 2018.
15. The Sustainability of Habitability on Terrestrial Planets: Insights, Questions, and Needed Measurements from Mars for Understanding the Evolution of Earth-like Worlds
    Ehlmann, B., et al. (47 coauthors), J. Geophysical Research Planets, 121, 1927-1961, doi:10.1002/2016JE005134, 2016.
16. Tidal Evolution of the Moon from a High-Obliquity High-Angular-Momentum Earth
    Ćuk, M., S. T. Stewart, S. J. Lock, D. Hamilton, Nature, 539, 402–406, doi:10.1038/nature19846, 2016.
17. Erosive Hit-and-Run Impact Events: Debris Unbound
    Sarid, G., S. T. Stewart, Z. M. Leinhardt. In Asteroids: New Observations, New Models, Proceedings IAU Symposium 318, 9-15, doi:10.1017/S1743921315009679, 2016.
18. Compositional Evolution during Rocky Planet Accretion
    Carter, P. J., Z. M. Leinhardt, T. Elliott, M. J. Walter, S. T. Stewart. Astrophysical Journal 813, 72 (17pp), doi:10.1088/0004-637X/813/1/72, 2015. Movies
19. A Collisional Origin to Earth’s Non-chondritic Composition?
    Bonsor, A., Z. M. Leinhardt, P. J. Carter, T. Elliott, M. J. Walter, S. T. Stewart. Icarus 247, 291-300, doi:10.1016/j.icarus.2014.10.019, 2015.
20. Shadows Cast on Moon’s Origin
    Elliot, T., S. T. Stewart. Nature 504, 90-91, doi:10.1038/504090a, 2013. A Planetary Science Forum
21. Collisions between Gravity-Dominated Bodies: II. The Diversity of Impact Outcomes during the End Stage of Planet Formation
    Stewart, S. T., Z. M. Leinhardt. Astrophysical Journal 751, 32 (17pp), doi:10.1088/0004-637X/751/1/32, 2012.
22. Collisions between Gravity-Dominated Bodies: I. Outcome Regimes and Scaling Laws
    Leinhardt, Z. M., S. T. Stewart. Astrophysical Journal 745, 79 (27pp), doi:10.1088/0004-637X/745/1/79, 2011.
    ⇒ Additional data comparisons and computer code.
23. Making the Moon from a fast-spinning Earth: A giant impact followed by resonant despinning
    Ćuk, M., S. T. Stewart. Science 338, 1047-1052, doi:10.1126/science.1225542, 2012. (Supplemental Materials PDF and Quicktime Movie 1, Movie 2, Movie 3)
24. Rebuttal to the Comment by Malhotra and Strom on “Constraints on the Source of Lunar Cataclysm Impactors”
    Ćuk, M., B. J. Gladman, S. T. Stewart. Icarus 216, 363-365, doi:10.1016/j.icarus.2011.08.011, 2011.
25. Water/Icy Super-Earths: Giant Impacts and Maximum Water Content
    Marcus, R. A., D. Sasselov, S. T. Stewart, L. Hernquist. Astrophysical Journal Letters 719, L45-L49, doi:10.1088/2041-8205/719/1/L45, 2010.
26. The Formation of the Collisional Family around the Dwarf Planet Haumea
    Leinhardt, Z. M., R. A. Marcus, S. T. Stewart. Astrophysical Journal 714, 1789-1799, doi:10.1088/0004-637X/714/2/1789, 2010. (Supplemental MPEG Movie)
27. Minimum Radii of Super-Earths: Constraints from giant impacts
    Marcus, R. A., D. Sasselov, L. Hernquist, S. T. Stewart. Astrophysical Journal Letters 712, L73-L76, doi:10.1088/2041-8205/712/1/L73, 2010.
28. Dynamical Evolution of the Hungaria Asteroids
    McEachern, F. M., M. Ćuk, S. T. Stewart. Icarus 210, 644-654, doi:10.1016/j.icarus.2010.08.003, 2010.
29. Constraints on the source of Lunar Cataclysm Impactors
    Ćuk, M., B. J. Gladman, S. T. Stewart. Icarus 207, 590-594, doi:10.1016/j.icarus.2009.12.013, 2010.
30. Collisional Stripping and Disruption of Super-Earths
    Marcus, R. A., S. T. Stewart, D. Sasselov, L. Hernquist. Astrophysical Journal Letters 700, L118-L122, doi:10.1088/0004-637X/700/2/L118, 2009.
31. Velocity-dependent Catastrophic Disruption Criteria for Planetesimals
    Stewart, S. T., Z. M. Leinhardt. Astrophysical Journal Letters 691, L133-L137, doi:10.1088/0004-637X/691/2/L133, 2009.
32. Full Numerical Simulations of Catastrophic Small Body Collisions
    Leinhardt, Z. M., S. T. Stewart. Icarus 199, 542-559, doi:10.1016/j.icarus.2008.09.013, 2009.
33. Physical effects of collisions in the Kuiper belt
    Leinhardt, Z. M., S. T. Stewart, P. H. Schultz. In The Solar System Beyond Neptune, Eds. A. Barucci, et al., U. Arizona Press, Tucson, p. 195-211, 2008.

1. Mercury Impact Origin Hypothesis Survives the Volatile Crisis: Implications for Terrestrial Planet Formation
   Stewart, S. T., S. J. Lock, M. I. Petaev, S. B. Jacobsen, G. Sarid, Z. M. Leinhardt, S. Mukhopadhyay, M. Humayun. Lunar and Planetary Science Conference 47, Abs. 2954, 2016.
2. How Much of the Mantle Melts in a Giant Impact?
   Stewart S. T., S. J. Lock, S. Mukhopadhyay. Lunar and Planetary Science Conference 46, Abs. 2263, 2015.
3. Giant Impacts, Volatile Loss, and the K/Th Ratios on the Moon, Earth, and Mercury.
   Stewart, S. T., Z. M. Leinhardt, M. Humayun. Lunar and Planetary Science Conference 44, Abs. 2306, 2013.
4. Late Impacts and the Origins of the Atmospheres on Venus, Earth, and Mars.
   Stewart, S. T., S. Mukhopadhyay. Lunar and Planetary Science Conference 44, Abs. 2419, 2013.
5. Atmospheric Loss during High Angular Momentum Giant Impacts.
   Lock, S. J., S. T. Stewart. Lunar and Planetary Science Conference 44, Abs. 2608, 2013.
6. Porosity effects on impact processes in the solar system.
   Stewart, S. T., and T. J. Ahrens.Lunar and Planetary Science Conference 30, Abs. 2020, 1999.

Shock and High Pressure Processes in Ice and Cratering on Icy Planets

1. Impacts onto H₂O Ice: Scaling Laws for Melting, Vaporization, Excavation, and Final Crater Size
   Kraus, R. G., L. E. Senft, S. T. Stewart. Icarus 214, 724-738, doi:10.1016/j.icarus.2011.05.016, 2011.
2. Modeling the morphological diversity of impact craters on icy satellites
   Senft, L. E., S. T. Stewart. Icarus 214, 67-81, doi:10.1016/j.icarus.2011.04.015, 2011.
3. Convergent Raman features in high density amorphous ice, ice VII, and ice VIII under pressure
   Yoshimura, Y., S. T. Stewart, M. Somayazulu, H.-K. Mao, R. J. Hemley. J. Physical Chemistry B 115, 3756-3760, doi:10.1021/jp111499x, 2011.
4. Shock and Post-Shock Temperatures in an Ice-Quartz Mixture: Implications for Melting during Planetary Impact Events
   Kraus, R. G., S. T. Stewart, A. Seifter, A. W. Obst. Earth and Planetary Science Letters 289, 162-170, doi:10.1016/j.epsl.2009.11.002, 2010. (Supplemental Materials)
5. Rampart craters on Ganymede: Their implications for fluidized ejecta emplacement
   Boyce, J., N. Barlow, P. Mouginis-Mark, S. Stewart. Meteoritics and Planetary Science 45, 638-661, doi:10.1111/j.1945-5100.2010.01044.x, 2010.
6. Shocked H₂O Ice: Thermal Emission Measurements and the Criteria for Phase Changes during Impact Events
   Stewart, S. T., A. Seifter, A. W. Obst. Geophysical Research Letters 35, L23203, doi:10.1029/2008GL035947, 2008. (Auxiliary materials)
7. In situ Raman spectroscopy of low-temperature/high-pressure transformations of H₂O
   Yoshimura, Y., S. T. Stewart, H.-K. Mao, R. J. Hemley. J. Chemical Physics 126, 174505, doi:10.1063/1.2720830, 2007.
8. High-pressure x-ray diffraction and Raman spectroscopy of ice VIII
   Yoshimura, Y., S. T. Stewart, M. Somayazulu, H.-K. Mao, R. J. Hemley. J. Chemical Physics 124, 024502, doi:10.1063/1.2140277, 2006.
9. Shock Properties of H₂O ice
   Stewart, S.T., T. J. Ahrens. J. Geophysical Research: Planets 110, E03005, doi:10.1029/2004JE002305, 2005. (Auxiliary materials)
10. A New H₂O Ice Hugoniot: Implications for Planetary Impact Events
    Stewart, S. T., T. J. Ahrens. In Shock Compression of Condensed Matter-2003, AIP Conference Proceedings 706, p. 1478-1483, Eds. M.D. Furnish, Y. M. Gupta, and J. W. Forbes, American Institute of Physics, doi:10.1063/1.1780518, 2004.
11. Shock Hugoniot of H₂O ice
    Stewart, S. T., T. J. Ahrens. Geophysical Research Letters 30, 1332, doi:10.1029/2002GL016789, 2003.
12. Shock Wave Propagation in Porous Ice
    Stewart, S. T., T. J. Ahrens. In Shock Compression of Condensed Matter-1999, AIP Conference Proceedings 505, p.1243-1246. Eds. M. D. Furnish, L. C. Chhabildas, R. S. Hixon. American Institute of Physics, doi:10.1063/1.1303686, 2000.

1. Beating Up Pluto: Modeling Large Impacts with Strength
   Davies, E. J., S. T. Stewart. Lunar and Planetary Science Conference 47, Abs. 2938, 2016.
2. Impacts onto Icy Bodies: A Journey from the Laboratory to the Outer Solar System
   Stewart, S. T. 41st Division for Planetary Sciences Meeting, Abs. 12.01, 2009. Urey Prize Lecture (slides PDF)
3. Advances in Modeling Impacts onto H₂O Ice.
   Stewart, S. T. 16th APS Topical Conference on Shock Compression of Condensed Matter, Abs. T3.00001, 2009. Invited. (slides PDF)
4. Correction to the dynamic tensile strength of ice and ice-silicate mixtures (Lange & Ahrens 1983).
   Stewart, S. T., and T. J. Ahrens. Lunar and Planetary Science Conference 30, Abs. 2037, 1999.

The Cratering Record and Volatiles on Mars and the Moon

1. A new large-scale map of the lunar crustal magnetic field and its interpretation
   Hood, L. L., C. B. Torres, J. S. Oliveira, M. A. Wieczorek, S. T. Stewart, J. Geophysical Research: Planets 126, doi:10.1029/2020JE006667, 2021.
2. Magnetic anomalies in five lunar impact basins: Implications for impactor trajectories and inverse modeling
   Hood, L. L., J. S. Oliveira, J. Andrews- Hanna, M. A. Wieczorek, S. T. Stewart, J. Geophysical Research: Planets 126, doi:10.1029/2020JE006668, 2021.
3. Demagnetization by basin-forming impacts on early Mars: Contributions from shock, heat and excavation
   Lillis, R. J., S. T. Stewart, M. Manga. J. Geophysical Research: Planets 118, 1045-1062, doi:10.1002/jgre.20085, 2013.
4. An impactor origin for lunar magnetic anomalies
   Wieczorek, M. A., B. P. Weiss, S. T. Stewart, Science 335, 1212-1215, doi:10.1126/science.1214773, 2012. (Supplemental Materials)
5. Impact demagnetization of the Martian crust: Current knowledge and future directions
   Louzada, K. L., S. T. Stewart, B. P. Weiss, J. Gattacceca, R. J. Lillis, J. S. Halekas. Earth and Planetary Science Letters 305, 257-269, doi:10.1016/j.epsl.2011.03.013, 2011. An EPSL Frontiers Article.
6. Study of impact demagnetization at Mars using Monte Carlo modeling and multiple altitude data
   Lillis, R. J., M. E. Purucker, J. S. Halekas, K. L. Louzada, S. T. Stewart-Mukhopadhyay, M. Manga, H. V. Frey. J. Geophysical Research: Planets 115, E07007, doi:10.1029/2009JE003556, 2010.
7. Impact Crater Formation in Icy Layered Terrains on Mars
   Senft, L. E., S. T. Stewart. Meteoritics and Planetary Science 43 (12), 1993-2013, doi:10.1111/j.1945-5100.2008.tb00657.x, 2008.
8. Excess ejecta craters record episodic ice-rich layers at middle latitudes on Mars
   Black, B. A., S. T. Stewart. J. Geophysical Research: Planets 113 (E2), E02015, doi:10.1029/2007JE002888, 2008.
9. Martian subsurface properties and crater formation processes inferred from fresh impact crater geometries
   Stewart, S. T., G. J. Valiant. Meteoritics and Planetary Sciences 41, 1509-1537, doi:10.1111/j.1945-5100.2006.tb00433.x, 2006.
10. The Role of Volatiles and Atmospheres on Martian Impact Craters
    Barlow, N., S. Stewart, O. Barnouin-Jha. EOS, Transactions, American Geophysical Union 86 (4), 433, doi:10.1029/2005EO440009, 2005.
11. Impact-Induced Melting of Near-Surface Water Ice on Mars
    Stewart, S. T., T. J. Ahrens, J. D. O’Keefe. In Shock Compression of Condensed Matter-2003, AIP Conference Proceedings 706, p. 1484-1487, Eds. M.D. Furnish, Y. M. Gupta, and J. W. Forbes, American Institute of Physics, doi:10.1063/1.1780519, 2004.
12. Surface runoff features on Mars: Testing the carbon dioxide formation hypothesis
    Stewart, S. T., F. Nimmo. J. Geophysical Research: Planets 107, 5069, doi:10.1029/2000JE001465, 2002.

Impact Cratering Mechanics

1. Dynamic Fault Weakening and the Formation of Large Impact Craters
   Senft, L. E., S. T. Stewart. Earth and Planetary Science Letters 287, 471-482, doi:10.1016/j.epsl.2009.08.033, 2009.
   (Supplemental Materials and Quicktime Movie 1, Movie 2)
2. Effects of Planet Curvature and Crust on the Shock Pressure Field around Impact Basins
   Louzada, K. L., S. T. Stewart. Geophysical Research Letters 36, L15203, doi:10.1029/2009GL037869, 2009. (Auxiliary Materials)
3. Modeling Impact Cratering in Layered Surfaces
   Senft, L. E., S. T. Stewart. J. Geophysical Research: Planets 112 (E11), E11002, doi:10.1029/2007JE002894, 2007.
4. Damage and rock-volatile mixture effects on impact crater formation
   O’Keefe, J. D., S. T. Stewart, M. E. Lainhart, T. J. Ahrens. International Journal of Impact Engineering 26, 543-553, doi:10.1016/S0734-743X(01)00112-9, 2001.

1. Impact Basin Formation and Structure from 3D Simulations
   S. T. Stewart. Lunar and Planetary Science Conference 43, Abs. 2865, 2012.
2. Impact Basin Formation: The Mantle Excavation Paradox Resolved
   Stewart, S. T. Lunar and Planetary Science Conference 42, Abs. 1633, 2011.
3. The Crustal Structure of Orientale and Implications for Basin Formation
   Andrews-Hanna, J. C., S. T. Stewart. Lunar and Planetary Science Conference 42, Abs. 2194, 2011.
4. Fault Weakening and Shear Localization during Crater Collapse
   Zucker, R. V., S. T. Stewart. Lunar and Planetary Science Conference 41, Abs. 2460, 2010.
5. Toward an Impact Basin Formation Scaling Law
   Stewart, S. T. Lunar and Planetary Science Conference 41, Abs. 2722, 2010.

Shock Processing of Natural Materials: Magnetism, Temperatures, Dehydration

1. Measuring the melting curve of iron at super-Earth core conditions
   Kraus, R.G., Hemley, R.J., Ali, S.J., Belof, J.L., Benedict, L.X., Bernier, J., Braun, D., Cohen, R.E., Collins, G.W., Coppari, F., Desjarlais, M.P., Fratanduono, D., Hamel, S., Krygier, A., Lazicki, A., Mcnaney, J., Millot, M., Myint, P.C., Newman, M.G., Rygg, J.R., Sterbentz, D.M., Stewart, S.T., Stixrude, L., Swift, D.C., Wehrenberg, C., Eggert, J.H., Science 80, 202, doi:10.1126/science.abm1472, 2022.
2. The Principal Hugoniot of Iron-Bearing Olivine to 1465 GPa
   Chidester, B. A., M. Millot, J. P. Townsend, D. K. Spaulding, E. J. Davies, S. Root, P. Kalita, D. E. Fratanduono, S. B. Jacobsen, S. T. Stewart, Geophysical Research Letters 48, doi:10.1029/2021GL092471, 2021.
3. Temperature and Density on the Forsterite Liquid-Vapor Phase Boundary
   Davies, E. J., M. S. Duncan, S. Root, R. G. Kraus, D. K. Spaulding, S. B. Jacobsen, and S. T. Stewart, J. Geophysical Research: Planets 126, doi:10.1029/ 2020JE006745, 2021.
4. Construction and Calibration of a Streaked Optical Spectrometer for Shock Temperature
   Davies, E. J., D. K. Spaulding, S. T. Stewart, In J. Lane, T. Germann, and M. Armstrong (Eds.), 21st Biennial APS Conference on Shock Compression of Condensed Matter (SCCM19), AIP Conference Proceedings 2272, 060008, doi:10.1063/12.0000834,2020. (arXiv:2005.14227)
5. Silicate Melting and Vaporization during Rocky Planet Formation
   Davies, E. J., P. J. Carter, S. Root, R. G. Kraus, D. K. Spaulding, S. T. Stewart, S. B. Jacobsen, J. Geophysical Research: Planets 125, e2019JE006227, doi:10.1029/2019JE006227, 2020.
6. The Shock Physics of Giant Impacts: Key Requirements for the Equations of State
   Stewart, S., E. Davies, M. Duncan, S. Lock, S. Root, J. Townsend, R. Kraus, R. Caracas, S. Jacobsen, In J. Lane, T. Germann, and M. Armstrong (Eds.), 21st Biennial APS Conference on Shock Compression of Condensed Matter (SCCM19), AIP Conference Proceedings 2272, 080003, 2020. (arXiv:1910.04687)
7. The principal Hugoniot of forsterite to 950 GPa
   Root, S., J. P. Townsend, E. Davies, R. W. Lemke, D. E. Bliss, D. E. Fratanduono, R. G. Kraus, M. Millot, D. Spaulding, L. Shulenburger, S. T. Stewart, S. B. Jacobsen, Geophysical Research Letters 45, 3865-3872, doi:10.1029/2017GL076931, 2018.
8. Investigating the Shock Response of Dry and Water- Saturated Sand: Flyer-Plate Experiments and Mesoscale Simulations
   LaJeunesse, J. W., J. P. Borg, S. T. Stewart, N. N. Thadhani. AIP Conference Proceedings 1979, 110007, doi:10.1063/1.5044926, 2018.
9. Dynamic Response of Dry and Water-Saturated Sand Systems
   LaJeunesse, J. W., M. Hankin, G. B. Kennedy, D. K. Spaulding, M. G. Schumaker, C. H. Neel, J. P. Borg, S. T. Stewart, N. N. Thadhani, Journal of Applied Physics, 122, 015901, doi:10.1063/1.4990625, 2017.
10. Stress and Temperature Distributions of Individual Particles in a Shock Wave Propagating through Dry and Wet Sand Mixtures
    Schumaker, M. T., G. Kennedy, N. Thadhani, M. Hankin, S. T. Stewart, J. P. Borg. AIP Conference Proceedings 1793, 120016, doi:10.1063/1.4971698, 2017.
11. Investigating velocity spectra at the Hugoniot state of shock loaded heterogenous materials
    LaJeunesse, J. W., S. T. Stewart, G. Kennedy, N. Thadhani, J. P. Borg. AIP Conference Proceedings 1793, 120007, doi:10.1063/1.4971689, 2017
12. Impact vaporization of planetesimal cores in the late stages of planetformation
    Kraus, R. G., S. Root, R. W. Lemke, S. T. Stewart, S. B. Jacobsen, and T. R. Mattsson. Nature Geoscience 8, 269-172, doi:10.1038/ngeo2369, 2015. (online supplementary material)
13. Uncertainties in shock devolatilization of hydrated minerals: A nontronite case study
    Kraus, R. G., S. T. Stewart, M. G. Newman, R. E. Milliken, N. J. Tosca. J. Geophysical Research: Planets 118, 1-9, doi:10.1002/jgre.20147, 2013.
14. Shock Vaporization of Silica and the Thermodynamics of Giant Impact Events
    Kraus, R. G., S. T. Stewart, D. C. Swift, C. A. Bolme, R. Smith, S. Hamel, B. Hammel, D. K. Spaulding, D. G. Hicks, J. H. Eggert, G. W. Collins. J. Geophysical Research: Planets 117, E09009, 22 pp., doi:10.1029/2012JE004082, 2012. (Auxiliary Material)
15. Shock and static pressure demagnetization of pyrrhotite and implications for the Martian crust
    Louzada, K. L., S. T. Stewart, B. P. Weiss, J. Gattacceca, N. S. Bezaeva. Earth and Planetary Science Letters 290, 90-101, doi:10.1016/j.epsl.2009.12.006, 2010. (Supplemental Materials)
16. Effect of shock on the magnetic properties of pyrrhotite, the Martian crust, and meteorites
    Louzada, K. L., S. T. Stewart, B. P. Weiss. Geophysical Research Letters 34, L05204, doi:10.1029/2006GL027685, 2007.
17. Shock Demagnetization of Pyrrhotite (Fe_1-xS,x<0.13) and Implications for the Martian Crust and Meteorites
    Louzada, K. L., S. T. Stewart, B. P. Weiss. In Shock Compression of Condensed Matter-2005, AIP Conference Proceedings 845, p. 1476-1479, Eds. M.D. Furnish, et al., American Institute of Physics, doi:10.1063/1.2263603, 2006.
18. Post-Shock Temperature and Free Surface Velocity Measurements of Basalt
    Stewart, S. T., G. B. Kennedy, L. E. Senft, M. R. Furlanetto, A. W. Obst, J. R. Payton, A. Seifter. In Shock Compression of Condensed Matter-2005, AIP Conference Proceedings 845, p. 1484-1487, Eds. M. D. Furnish et al., American Institute of Physics, doi:10.1063/1.2263605, 2006.
19. Post-Shock Temperature Measurements of Aluminum
    Seifter, A., S. T. Stewart, M. R. Furlanetto, G. B. Kennedy, J. R. Payton, A. W. Obst. In Shock Compression of Condensed Matter-2005, AIP Conference Proceedings 845, p. 139-142, Eds. M.D. Furnish, et al. American Institute of Physics, doi:10.1063/1.2263284, 2006.
20. Records of an ancient Martian magnetic field in ALH84001
    Weiss, B. P., H. Vali, F. J. Baudenbacher, J. L. Kirschvink, S. T. Stewart, D. L. Shuster. Earth and Planetary Science Letters 201, 449-464, doi:10.1016/S0012-821X(02)00728-8, 2002.
21. Temperatures on Mars: ⁴⁰Ar/³⁹Ar Thermochronology of ALH84001
    Weiss, B. P., D. L. Shuster, S. T. Stewart. Earth and Planetary Science Letters 201, 465-472, doi:10.1016/S0012-821X(02)00729-X, 2002.

1. Experimental Study of Shock-Induced Vaporization of Rocky Planet Constituents
   Davies, E. J., S. Root, S. T. Stewart, D. K. Spaulding, S. B. Jacobsen. Lunar and Planetary Science Conference 47, Abs. 3001, 2016.
2. Shock Thermodynamics of Mantle Rocks: Rockport Fayalite.
   Steinhardt, W. M., S. T. Stewart. Lunar and Planetary Science Conference 44, Abs. 2826, 2013.
3. Shock Demagnetization of Single Domain Magnetite.
   Louzada, K. L., S. T. Stewart, B. P. Weiss. Lunar & Planetary Science Conference 41, Abs. 1937, 2010.
4. Measurements of Emission Temperatures from Shocked Basalt: Hot spots in meteorites.
   Stewart, S. T., A. Seifter, G. B. Kennedy, M. R. Furlanetto, and A. W. Obst. Lunar & Planetary Science Conference 38, Abs. 2413, 2007.
5. The Shock Compression Laboratory at Harvard: A New Facility for Planetary Impact Processes.
   Stewart, S. T. Lunar & Planetary Science Conference 35, Abs. 1290, 2004.

Lonar crater, India

1. Paleomagnetism of impact spherules from Lonar crater, India and a test for impact-generated fields
   Weiss, B. P., S. Pedersen, I. Garrick-Bethell, S. T. Stewart, K. L. Louzada, A. C. Maloof, N. L. Swanson-Hysell. Earth and Planetary Science Letters 298, 66-76, doi:10.1016/j.epsl.2010.07.028, 2010. (Supplemental text, spreadsheet, and movie.)
2. Geology of Lonar Crater, India
   Maloof, A. C., S. T. Stewart, B. P. Weiss, S. A. Soule, N. L. Swanson-Hysell, K. L. Louzada, I. Garrick-Bethell, P. M. Poussart. GSA Bulletin 122, 109-126, doi:10.1130/B26474.1, 2010. (Data Repository PDF – 91 Mb, Lonar DEM zip file – 13 Mb)
3. Paleomagnetism of Lonar Impact Crater, India
   Louzada, K. L., B. P. Weiss, A. C. Maloof, S. T. Stewart, N. Swanson-Hysell, S. A. Soule. Earth and Planetary Science Letters 275, 309-319, doi:10.1016/j.epsl.2008.08.025, 2008. (Supplemental Materials)

Miscellaneous

1. Is Enceladus Plume Tidally Controlled?
   Halevy, I., S. T. Stewart. Geophysical Research Letters 35, L12203, doi:10.1029/2008GL034349, 2008.
2. Evolution and persistence of 5-μm hot spots at the Galileo probe entry latitude
   Ortiz, J. L., G. S. Orton, A. J. Friedson, S. T. Stewart, B. M. Fisher, J. R. Spencer. J. Geophysical Research: Planets 103 (E10), 23051-23069, doi:10.1029/98JE00696, 1998.
3. Characteristics of the Galileo probe entry site from Earth-based remote sensing observations
   Orton, G. S., B. M. Fisher, K. H. Baines, S. T. Stewart, A. J. Friedson, J. L. Ortiz, M. Marinova, M. Ressler, A. Dayal, W. Hoffmann, J. Hora, S. Hinkley, V. Krishnan, M. Masanovic, J. Tesic, A. Tziolas, K. C. Parija.
   J. Geophysical Research: Planets 103 (E10), 22791-22814, doi:10.1029/98JE02380, 1998.
4. Earth-based observations of the Galileo probe entry site
   Orton, G., J. L. Ortiz, K. Baines, G. Bjoraker, U. Carsenty, F. Colas, A. Dayal, D. Deming, P. Drossart, E. Frappa, J. Friedson, J. Goguen, W. Golisch, D. Griep, C. Hernandez, W. Hoffmann, D. Jennings, C. Kaminski, J. Kuhn, P. Laques, S. Limaye, H. Lin, J. Lecacheux, T. Martin, G. McCabe, T. Momary, D. Parker, R. Puetter, M. Ressler, G. Reyes, P. Sada, J. Spencer, J. Spitale, S. Stewart, J. Varsik, J. Warell, W. Wild, P. Yanamandra-Fisher, G. Fazio, J. Hora, L. Deutsch. Science 272, 839-840, doi:10.1126/science.272.5263.839, 1996.