Lu Pan
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Anatomy of the compositional evolution in martian deltas 火星三角洲的矿物成分演化
Temporal and spatial distribution of martian dust 火星尘的时空分布
Radiative transfer with imaging meteorites 陨石光谱的辐射传输模型
A machine learning approach to distangle spectral data 光谱混合模型中机器学习应用
Environmental impact 撞击的环境影响
Records of ancient planetary impacts 行星的撞击记录
InSight’s exploration of Mars’ interior 洞察号火星车探索内部结构
Gale crater exploration in support for MSL mission 好奇号火星车盖尔撞击坑的探测
Supporting Tianwen-1 and Zhurong 天问一号和祝融号火星车
[30] Kepp M*., L. Pan, J. Frydenvang, M., Bizzarro, Orbital identification of widespread hydrated silica deposits in Gale crater, in review.
[29] Deng Z., K. Nikolajsen, M. Schiller, L. Pan, M., Bizzarro, Redox evolutions of planetary mantle reservoirs constrained by titanium isotopes, in review.
[28] Deng Z., M. Schiller, M. G. Jackson, M.-A. Millet, L. Pan, K. Nikolajsen, N. S. Saji, D. Huang, M. Bizzarro, Earth's evolving geodynamic regime recorded by titanium isotopes, Nature, 2023: 1-5. [link]
[27] Xu Z., A. Broquet, N. Fuji, T. Kawamura, P. Lognonne , J.-P. Montagner, L. Pan, M. Schimmel , E. Stutzmann , W. B. Banerdt. Investigation of Martian Regional Crustal Structure Near the Dichotomy Using S1222a Surface-Wave Group Velocities, Geophys. Res. Lett., 2023, vol 50, issue 8, e2023GL103136. [link]
[26] Zhang Z., H. Jiang, P. Ju, L. Pan, J. Roulliard, G.-T. Zhou, J. Hao, Synthesis/destruction of building blocks of life during impact-induced hydrothermal activities on the primitive Earth? Frontiers in Microbiology, 2023, vol 14, 10.3389/fmicb.2023.1032073. [link]
[25] Pan, L., Z. Deng, M. Bizarro. Impact induced oxidation and its implications for early Mars climate, Geophys. Res. Lett., 2023, 50, e2023GL102724. [link] 【EoS报道】
[24] Zhao Y. Y.-S., J. Yu, G.-F. Wei, L. Pan, X. Wang, J.-T. Wang, Y. Liu, X. Wu, X.-Zeng, X.-Y. Li, X.-Y. Li, G. Bao, X.-W. Yu, S.-Y. Qu, C. Sun, W. Xu, Y. Rao, T. Sun, F. Chen, B. Zhang, W.-M. Xu, X.-F. Liu, Y.-T. Lin, J.-Z. Liu, In situ analysis of surface composition and meteorology at the Zhurong landing site on Mars, National Science Review, 2023, nwad056. [link]
[23] Zhu K., M. Schiller, L. Pan, N. S. Saji, K. K. Larsen, E. Ansellem, C. Roudaug, P.Sossi, F. Moynier, M. Bizarro, Late delivery of exotic chromium to the crust ofMars by water-rich asteroids, Science Advances, 2022, 8, 46, 10.1126/sciadv.abp8415. [link]
[22] Carrasco S., B. Knapmeyer-Endrun, L. Margerin, C. Schmelzbach, K. Onodera, L. Pan, P. Lognonné, S. Menina, D. Giardini, E. Stutzmann, J. Clinton, S. Stähler, M. Schimmel, M. Golombek, M. Hobiger, M. Hallo, S. Kedar and W. B. Banerdt, Empirical H/V spectral ratios at the InSight landing site and implications for the Martian subsurface structure. Geophys. J. Int., 2022, 232, 2, 1293–1310. [link]
[21] Liu Y., X. Wu, Y-Y. S. Zhao, L. Pan, C. Wang, J. Liu, Z. Zhao, X. Zhou, C. Zhang,Y. Wu, Y. Zou. Zhurong reveals recent aqueous activities in Utopia Planitia,Mars, Science Advance, 2022, 8, 19, 10.1126/sciadv.abn8555. [link]
[20] Warner N. H., M. P. Golombek, V. Ansan, E. Marteau, N. Williams, J. A. Grant, E. Hauber,C. Weitz, S. Wilson, S. Piqueux, N. Mueller, M. Grott, T. Spohn, L. Pan , C.Schmelzbach, I. Daubar, J. Garvin, C. Charalambous, M. Baker, M. Banks, In Situand Orbital Stratigraphic Characterization of the InSight Landing Site - A TypeExample of a Regolith-Covered Lava Plain on Mars. Journal of GeophysicalResearch: Planets, 2022, 127, e2022JE007232. [link]
[19] Breton, S., C. Quantin-Nataf, L. Pan, L. Mandon, and M. Volat. 2022. Insight intoMartian Crater Degradation History Based on Crater Depth and DiameterStatistics. Icarus 377 (May): 114898. [link]
[18] Pan, L., C. Quantin-Nataf, L.Mandon, M. Martinot, and P. Beck. 2021. “SpectralEndmember Variability on Hyperspectral Datasets of a Martian Meteorite —Implications for Planetary Surfaces.” Icarus 370 (December):114656. [link]
[17] Knapmeyer-Endrun B., M. P. Panning et al. (incl. L. Pan), Thickness andstructure of the Martian crust from InSight seismic data, Science,2021, 373, 6553, pp. 438-443, [link].
[16] Mandon L., P. Beck, C. Quantin-Nataf, E. Dehouck, A. Pommerol, Z. Yoldi, R.Cerubini, L.Pan, M. Martinot, J.-A. Barrat, B. Reynard, Martianmeteorites reflectance and implications forin situ studies, Icarus,366, 114517, [link].
[15] Pan, L., J. Carter, C.Quantin-Nataf, M. Pineau, B. Chauvire, L. Le Deit, N. Mangold, B. Rondeau, V.Chevrier. Voluminous silicaprecipitation in late martian waters, Planetary Science Journal,(2021) 2 65, [link].
[14] Liu Z., Y. Liu, L. Pan, J. Zhao, Inverted channel belt to the East ofTempe Terra, Mars, and implications for persistent fluvial activity. Earthand Planetary Science Letters, (2021)562, 116854, [link].
[13] Mandon L., A. Parkes Bowen, C. Quantin-Nataf, J. C. Bridges, J. Carter, L. Pan,P. Beck, E. Dehouck, M. Volat, N. Thomas, G. Cremonese, L. L. Tornabene,Morphological and spectral diversity of the clay-bearing unit at the ExoMarslanding site Oxia Planum, Astrobiology, 2021 21:4, 464-480., [link].
[12] Quantin-Nataf C., J. Carter, L. Mandon, P. Thollot, M. Balme, M. Volat,L. Pan, D.,Loizeau, C. Millot, S. Breton, E. Dehouck, P. Fawdon, S. Gupta, J. Davis, P.M.,Grindrod, A. Pacifici, B. Bultel, P. Allemand, A. Ody, L. Lozach, J. Broyer,Oxia Planum – the landing site for the 2022 ExoMars “Rosalind Franklin” RoverMission: geological context and pre-landing interpretation, Astrobiology, 2021, [link].
[11] Perrin C., Rodriguez, S., Jacob, A., Lucas, A., Spiga, A., Murdoch, N., Lorenz, R.,Daubar, I. J., L. Pan, Kawamura, T., Lognonne, P., Banfield, D.,Banks, M. E., Garcia, R. F., Newman, C. E., Ohja, L., Widmer-Schnidrig, R.,McEwen, A. S., Banerdt, W. B. (2020) Dust Devil Tracks Around the InSight Landing Site, Mars: 8 Months of Monitoring from HiRISE Satellite Images andComparison with in-situ Atmospheric Data , Geophy. Res. Lett., [link].
[10] Pan, L., C. Quantin-Nataf, B.Tauzin, C. Michaut, M. Golombek, P. Lognonné, P. Grindrod, B. Langlais, T.Gudkova, I. Stepanova, S. Rodriguez, A. Lucas.(2020) Crust heterogeneities andstructure in the first kilometers at the dichotomy boundary in western Elysium Planitiaand Implications for InSight lander, Icarus, 338, [link].
[9] Lognonné, P., W. B. Banerdt, W. T. Pike, D.Giardini et al. (incl. L. Pan)(2020) Constraints on the shallow elastic and anelastic structure of Mars fromInSight seismic data, Nature Geoscience, [link].
[8] Johnson C., A. Mittelholz et al. (incl. L. Pan).(2020) Crustal andTime-Varying Magnetic Fields at the InSight Landing Site on Mars, NatureGeoscience, [link].
[7] Pan, L., C. Quantin-Nataf, S.Breton, and C. Michaut. (2019). The ImpactOrigin and Evolution of Chryse Planitia on Mars Revealed by BuriedCraters. Nature Communications 10 (1): 4257, [link].
[6] Pan, L., and Ehlmann, B. L.(2018). Aqueous processes from diverse hydrous minerals in the vicinity ofAmazonian aged Lyot crater. Journal of Geophysical Research: Planets,123, 1618–1648, [link].
[5]Tian W., L. Wang, L. Pan and M. Y. Gong (2018) A giant felsicpyroclastic flow eruption in the Tarim Flood Basalt Province, ActaPetrologica Sinica. 34 (1): 63-74.
[4] Buz J., B. L. Ehlmann, L. Pan, and J. P. Grotzinger (2017), Mineralogyand stratigraphy of the Gale crater rim, wall, and floor units, J.Geophys. Res. Planets, 122, 1090–1118, [link].
[3] Pan, L., Ehlmann, B. L.,Carter, J., Ernst, C. M. (2017) The stratigraphy and history ofMars' northern lowlands through mineralogy of impact craters: Acomprehensive survey. Journal of Geophysical Research: Planets ,122(9), 1824-1854. [link].
[2] Pan, L., and B. L. Ehlmann(2014), Phyllosilicate and hydrated silica detections in the knobby terrains ofAcidalia Planitia, northern plains, Mars, Geophys. Res. Lett., 41,1890–1898, [link].
[1] Shangguan S.M., T. Wei, Y.G. Xu, P. Guan, L. Pan (2012) The eruptioncharacteristic of the Tarim flood basalt., Acta Petrologica Sinica.28(4): 1261-1272
