Xu, Y. and Arridge, C. S. and Yao, Z. H. and Zhang, B. and Ray, L. C. and Badman, S. V. and Dunn, W. R. and Ebert, R. W. and Chen, J. J. and Allegrini, F. and Kurth, W. S. and Qin, T. S. and Connerney, J. E. P. and McComas, D. J. and Bolton, S. J. and Wei, Y. (2024) In situ evidence of the magnetospheric cusp of Jupiter from Juno spacecraft measurements. Nature Communications, 15 (1): 6062. ISSN 2041-1723
Full text not available from this repository.Abstract
The magnetospheric cusp connects the planetary magnetic field to interplanetary space, offering opportunities for charged particles to precipitate to or escape from the planet. Terrestrial cusps are typically found near noon local time, but the characteristics of the Jovian cusp are unknown. Here we show direct evidence of Jovian cusps using datasets from multiple instruments onboard Juno spacecraft. We find that the cusps of Jupiter are in the dusk sector, which is contradicting Earth-based predictions of a near-noon location. Nevertheless, the characteristics of charged particles in the Jovian cusps resemble terrestrial and Saturnian cusps, implying similar cusp microphysics exist across different planets. These results demonstrate that while the basic physical processes may operate similarly to those at Earth, Jupiter’s rapid rotation and its location in the heliosphere can dramatically change the configuration of the cusp. This work provides useful insights into the fundamental consequences of star-planet interactions, highlighting how planetary environments and rotational dynamics influence magnetospheric structures.