Hopp, T.; Kleine, T.: Nature of late accretion to Earth inferred from mass-dependent Ru isotopic compositions of chondrites and mantle peridotites. Earth and Planetary Science Letters 494, pp. 50 - 59 (2018)
Matthes, M.; Fischer-Gödde, M.; Kruijer, T. S.; Kleine, T.: Pd-Ag chronometry of IVA iron meteorites and the crystallization and cooling of a protoplanetary core. Geochimica et Cosmochimica Acta 220, pp. 82 - 95 (2018)
Neumann, W.; Kruijer, T. S.; Breuer, D.; Kleine, T.: Multistage Core Formation in Planetesimals Revealed by Numerical Modeling and Hf-W Chronometry of Iron Meteorites. Journal of Geophysical Research (Planets) 123, pp. 421 - 444 (2018)
Render, J.; Brennecka, G. A.; Wang, S.-J.; Wasylenki, L. E.; Kleine, T.: A Distinct Nucleosynthetic Heritage for Early Solar System Solids Recorded by Ni Isotope Signatures. The Astrophysical Journal 862, p. 26 (2018)
Bast, R.; Scherer, E. E.; Sprung, P.; Mezger, K.; Fischer-Gödde, M.; Taetz, S.; Böhnke, M.; Schmid-Beurmann, H.; Münker, C.; Kleine, T.et al.; Srinivasan, G.: Reconciliation of the excess 176Hf conundrum in meteorites: Recent disturbances of the Lu-Hf and Sm-Nd isotope systematics. Geochimica et Cosmochimica Acta 212, pp. 303 - 323 (2017)
Brennecka, G. A.; Kleine, T.: A Low Abundance of 135Cs in the Early Solar System from Barium Isotopic Signatures of Volatile-depleted Meteorites. The Astrophysical Journal 837, p. L9 (2017)
Gerber, S.; Burkhardt, C.; Budde, G.; Metzler, K.; Kleine, T.: Mixing and Transport of Dust in the Early Solar Nebula as Inferred from Titanium Isotope Variations among Chondrules. The Astrophysical Journal 841, p. L17 (2017)
Herd, C. D. K.; Walton, E. L.; Agee, C. B.; Muttik, N.; Ziegler, K.; Shearer, C. K.; Bell, A. S.; Santos, A. R.; Burger, P. V.; Simon, J. I.et al.; Tappa, M. J.; McCubbin, F. M.; Gattacceca, J.; Lagroix, F.; Sanborn, M. E.; Yin, Q.-Z.; Cassata, W. S.; Borg, L. E.; Lindvall, R. E.; Kruijer, T. S.; Brennecka, G. A.; Kleine, T.; Nishiizumi, K.; Caffee, M. W.: The Northwest Africa 8159 martian meteorite: Expanding the martian sample suite to the early Amazonian. Geochimica et Cosmochimica Acta 218, pp. 1 - 26 (2017)
Krabbe, N.; Kruijer, T. S.; Kleine, T.: Tungsten stable isotope compositions of terrestrial samples and meteorites determined by double spike MC-ICPMS. Chemical Geology 450, pp. 135 - 144 (2017)
Kruijer, T. S.; Burkhardt, C.; Budde, G.; Kleine, T.: Age of Jupiter inferred from the distinct genetics and formation times of meteorites. Proceedings of the National Academy of Science 114, pp. 6712 - 6716 (2017)
Kruijer, T. S.; Kleine, T.; Borg, L. E.; Brennecka, G. A.; Irving, A. J.; Bischoff, A.; Agee, C. B.: The early differentiation of Mars inferred from Hf-W chronometry. Earth and Planetary Science Letters 474, pp. 345 - 354 (2017)
Render, J.; Fischer-Gödde, M.; Burkhardt, C.; Kleine, T.: The cosmic molybdenum-neodymium isotope correlation and the building material of the Earth. GEOCHEMICAL PERSPECTIVES LETTERS (2), pp. 170 - 178 (2017)
Bezard, R.; Fischer-Gödde, M.; Hamelin, C.; Brennecka, G. A.; Kleine, T.: The effects of magmatic processes and crustal recycling on the molybdenum stable isotopic composition of Mid-Ocean Ridge Basalts. Earth and Planetary Science Letters 453, pp. 171 - 181 (2016)
Budde, G.; Burkhardt, C.; Brennecka, G. A.; Fischer-Gödde, M.; Kruijer, T. S.; Kleine, T.: Molybdenum isotopic evidence for the origin of chondrules and a distinct genetic heritage of carbonaceous and non-carbonaceous meteorites. Earth and Planetary Science Letters 454, pp. 293 - 303 (2016)
Budde, G.; Kleine, T.; Kruijer, T. S.; Burkhardt, C.; Metzler, K.: Tungsten isotopic constraints on the age and origin of chondrules. Proceedings of the National Academy of Science 113, pp. 2886 - 2891 (2016)
How does our star heat its outer atmosphere, the solar corona, to unimaginable temperatures of up to 10 million degrees Celsius? With unprecedented observational data from ESA's Solar Orbiter spacecraft and powerful computer simulations, ERC starting grant awardee Pradeep Chitta intends to bring new momentum to the search for the coronal heating mechanism.
The research group “Solar Lower Atmosphere and Magnetism” (SLAM) studies the conditions and dynamic processes in the atmospheric layer between the solar surface (photosphere) and the overlying chromosphere, an approximately 2000 km thick gas layer.
The main research fields of the department "Sun and Heliosphere" are covered by the research groups "Solar and Stellar Coronae", "Solar Lower Atmosphere and Magnetism", "Solar and Stellar Magnetohydrodynamics" and "Solar Variability and Climate".