Grensing, D.; Marsch, E.; Steeb, W.-H.: Magnetic and electric properties of the Hubbard model for the f.c.c. Lattice. Physical Review B 17, pp. 2221 - 2232 (1978)
Marsch, E.; Steeb, W.-H.; Grensing, D.: One-Dimensional Hubbard Model With Nearest and Second Nearest Neighbour Hopping in the Hartree-Fock Approximation. J. Phys. F: Metal Phys. 7, pp. 401 - 406 (1977)
Rosenbauer, H.; Schwenn, R.; Marsch, E.; Meyer, B.; Miggenrieder, H.; Montgomery, M.; Mühlhäuser, K.-H.; Pilipp, W.; Voges, W.; Zink, S. K.: A Survey on Initial Results of the Helios Plasma Experiment. J. Geophys. 42, pp. 561 - 580 (1977)
Marsch, E.: Force-force correlation function method for the ideal resistance of the Hubbard model. J. Phys. C: Solid State Phys. 9, pp. L117 - L120 (1976)
Steeb, W.-H.; Marsch, E.: Thermodynamics of a two-point doubly degenerate Hubbard model in the half-filled case. Phys. Stat. Sol. (b) 78, pp. K39 - K44 (1976)
Steeb, W.-H.; Marsch, E.: A new upper bound for the free energy of the Hubbard model based on the cluster approach. Phys. Stat. Sol. (b) 69, pp. K149 - K152 (1975)
Solanki, S. K.; Marsch, E.: Solar Space Missions: present and future. In: Formation and Evolution of Cosmic Structures: Reviews in Modern Astronomy, Volume 21, pp. 229 - 248 (Ed. Röser, S.). Wiley-VCH, Weinheim (2009)
Marsch, E.: Waves and turbulence in the solar corona. In: The Sun and the Heliosphere as an Integrated System, pp. 283 - 317 (Eds. Poletto, G.; Suess, S. T.). Kluwer Academic Publishers, Dordrecht, The Netherlands (2004)
Marsch, E.; Axford, W. I.; McKenzie, J. F.: Solar Wind. In: The Dynamic Sun, pp. 374 - 402 (Ed. Dwivedi, B.). Cambridge University Press, Cambridge (2003)
Marsch, E.: Solar Wind: Kinetic Properties. In: Encyclopedia of Astronomy and Astrophysics, pp. 2862 - 2866 (Ed. Murdin, P.). Institut of Physics Publishing, Nature Publishing Group (2001)
The MPS instruments on board ESA’s JUICE spacecraft have successfully completed their commissioning in space - and delivered their first observational data.
A collision nearly 30 years ago permanently changed Jupiter's atmospheric chemistry; the aftermath is still helping to better understand the gas giant.
The launch was successful; the ESA’s space probe JUICE is now on its way to the Jupiter system. There, it will primarily study the gas giant's icy moons.