Publikationen von Christoph Burkhardt

Jansen, C. A.; Burkhardt, C.; Marrocchi, Y.; Schneider, J. M.; Wölfer, E.; Kleine, T.: Condensate evolution in the solar nebula inferred from combined Cr, Ti, and O isotope analyses of amoeboid olivine aggregates. Earth and Planetary Science Letters 627, S. 118567 (2024)

Kleine, T.; Steller, T.; Burkhardt, C.; Burkhardt, C.; Nimmo, F.: An inner solar system origin of volatile elements by Mars. Icarus 397, 115519 (2023)

Hellmann, J. L.; Schneider, J. M.; Wölfer, E.; Drazkowska, J.; Jansen, C. A.; Hopp, T.; Burkhardt, C. M.; Kleine, T.: Origin of Isotopic Diversity among Carbonaceous Chondrites. The Astrophysical Journal 946, S. L34 (2023)

Schneider, J. M.; Burkhardt, C.; Kleine, T.: Distribution of s-, r-, and p-process Nuclides in the Early Solar System Inferred from Sr Isotope Anomalies in Meteorites. The Astrophysical Journal 952, S. L25 (2023)

Fridolin, S.; Burkhardt, C.; Pape, J.; Kleine, T.: Collisional mixing between inner and outer solar system planetesimals inferred from the Nedagolla iron meteorite. Meteoritics and Planetary Science 57, S. 261 - 276 (2022)

Kruijer, T. S.; Burkhardt, C.; Borg, L. E.; Kleine, T.: Tungsten and molybdenum isotopic evidence for an impact origin of pallasites. Earth and Planetary Science Letters 584, S. 117440 (2022)

Render, J.; Brennecka, G. A.; Burkhardt, C.; Kleine, T.: Solar System evolution and terrestrial planet accretion determined by Zr isotopic signatures of meteorites. Earth and Planetary Science Letters 595, S. 117748 (2022)

Renggli, C. J.; Hellmann, J. L.; Burkhardt, C.; Klemme, S.; Berndt, J.; Pangritz, P.; Kleine, T.: Tellurium isotope fractionation during evaporation from silicate melts. Geochimica et Cosmochimica Acta 339, S. 35 - 45 (2022)

Steller, T.; Burkhardt, C.; Yang, C.; Kleine, T.: Nucleosynthetic zinc isotope anomalies reveal a dual origin of terrestrial volatiles. Icarus 386, S. 115171 (2022)

Burkhardt, C.; Spitzer, F.; Morbidelli, A.; Budde, G.; Render, J. H.; Kruijer, T. S.; Kleine, T.: Terrestrial planet formation from lost inner solar system material. Science Advances 7 (52), eabj7601 (2021)