Your search keyword '"Shaikhislamov, I F"' showing total 3 results

1. 3D Aeronomy modelling of close-in exoplanets.

Author

Shaikhislamov, I F, Khodachenko, M L, Lammer, H, Berezutsky, A G, Miroshnichenko, I B, and Rumenskikh, M S

Subjects

*THREE-dimensional imaging in astronomy, *UPPER atmosphere, *EXTRASOLAR planets, *HYDRODYNAMICS, *JUPITER (Planet)

Abstract

We present a 3D fully self-consistent multifluid hydrodynamic aeronomy model to study the structure of a hydrogen-dominated expanding upper atmosphere around the hot Jupiter HD 209458b and the warm Neptune GJ 436b. In comparison to previous studies with 1D and 2D models, this work finds such 3D features as zonal flows in upper atmosphere reaching up to 1 km s−1, the tilting of the planetary outflow by Coriolis force by up to 45 degrees and its compression around equatorial plane by tidal forces. We also investigated in detail the influence of helium (He) on the structure of the thermosphere. It is found that by decrease of the barometric scale height, the He presence in the atmosphere strongly affects the H2dissociation front and the temperature maximum. [ABSTRACT FROM AUTHOR]

Published

2018

2. Effect of stellar wind induced magnetic fields on planetary obstacles of non-magnetized hot Jupiters.

Author

Erkaev, N. V., Odert, P., Lammer, H., Kislyakova, K. G., Fossati, L., Mezentsev, A. V., Johnstone, C. P., Kubyshkina, D. I., Shaikhislamov, I. F., and Khodachenko, M. L.

Subjects

STELLAR winds, MAGNETIC fields, JUPITER (Planet), MAGNETOHYDRODYNAMICS, MAGNETIC moments

Abstract

We investigate the interaction between themagnetized stellarwind plasma and the partially ionized hydrodynamic hydrogen outflow from the escaping upper atmosphere of non-magnetized or weakly magnetized hot Jupiters. We use the well-studied hot Jupiter HD 209458b as an example for similar exoplanets, assuming a negligible intrinsic magnetic moment. For this planet, the stellar wind plasma interaction forms an obstacle in the planet's upper atmosphere, in which the position of the magnetopause is determined by the condition of pressure balance between the stellar wind and the expanded atmosphere, heated by the stellar extreme ultraviolet radiation.We show that the neutral atmospheric atoms penetrate into the region dominated by the stellar wind, where they are ionized by photoionization and charge exchange, and then mixed with the stellar wind flow. Using a 3D magnetohydrodynamic (MHD) model, we show that an induced magnetic field forms in front of the planetary obstacle, which appears to be much stronger compared to those produced by the solar wind interaction with Venus and Mars. Depending on the stellar wind parameters, because of the induced magnetic field, the planetary obstacle can move up to ≈0.5-1 planetary radii closer to the planet. Finally, we discuss how estimations of the intrinsic magnetic moment of hot Jupiters can be inferred by coupling hydrodynamic upper planetary atmosphere andMHDstellar wind interaction models together with UV observations. In particular, we find that HD 209458b should likely have an intrinsic magnetic moment of 10-20 per cent that of Jupiter. [ABSTRACT FROM AUTHOR]

Published

2017

3. INFLATION OF A DIPOLE FIELD IN LABORATORY EXPERIMENTS: TOWARD AN UNDERSTANDING OF MAGNETODISK FORMATION IN THE MAGNETOSPHERE OF A HOT JUPITER.

Author

ANTONOV, V. M., BOYARINSEV, E. L., BOYKO, A. A., ZAKHAROV, YU. P., MELEKHOV, A. V., PONOMARENKO, A. G., POSUKH, V. G., SHAIKHISLAMOV, I. F., KHODACHENKO, M. L., and LAMMER, H.

Subjects

JUPITER (Planet), EXPERIMENTS, MAGNETOSPHERE, EXTRASOLAR planets, MAGNETIC dipoles, MAGNETOPAUSE

Abstract

Giant exoplanets at close orbits, or so-called hot Jupiters, are supposed to have an intensive escape of upper atmospheric material heated and ionized by the radiation of a host star. An interaction between outflowing atmospheric plasma and the intrinsic planetary magnetic dipole field leads to the formation of a crucial feature of a hot Jupiter's magnetosphere—an equatorial current-carrying magnetodisk. The presence of a magnetodisk has been shown to influence the topology of a hot Jupiter's magnetosphere and to change a standoff distance of the magnetopause. In this paper, the basic features of the formation of a hot Jupiter's magnetodisk are studied by means of a laboratory experiment. A localized central source produces plasma that expands outward from the surface of the dipole and inflates the magnetic field. The observed structure of magnetic fields, electric currents, and plasma density indicates the formation of a relatively thin current disk extending beyond the Alfvénic point. At the edge of the current disk, an induced magnetic field was found to be several times larger than the field of the initial dipole. [ABSTRACT FROM AUTHOR]

Published

2013