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How expanded ionospheres of Hot Jupiters can prevent escape of radio emission generated by the cyclotron maser instability

How expanded ionospheres of Hot Jupiters can prevent escape of radio emission generated by the cyclotron maser instability
How expanded ionospheres of Hot Jupiters can prevent escape of radio emission generated by the cyclotron maser instability
We present a study of plasma conditions in the atmospheres of the Hot Jupiters HD 209458b and HD 189733b and for an HD 209458b like planet at orbit locations between 0.2 and 1 au around a Sun-like star. We discuss how these conditions influence the radio emission we expect from their magnetospheres. We find that the environmental conditions are such that the cyclotron maser instability (CMI), the process responsible for the generation of radio waves at magnetic planets in the Solar system, most likely will not operate at Hot Jupiters. Hydrodynamically expanding atmospheres possess extended ionospheres whose plasma densities within the magnetosphere are so large that the plasma frequency is much higher than the cyclotron frequency, which contradicts the condition for the production of radio emission and prevents the escape of radio waves from close-in exoplanets at distances <0.05 au from a Sun-like host star. The upper atmosphere structure of gas giants around stars similar to the Sun changes between 0.2 and 0.5 au from the hydrodynamic to a hydrostatic regime, and this results in conditions similar to Solar system planets with a region of depleted plasma between the exobase and the magnetopause, where the plasma frequency can be lower than the cyclotron frequency. In such an environment, a beam of highly energetic electrons accelerated along the field lines towards the planet can produce radio emission. However, even if the CMI could operate, the extended ionospheres of Hot Jupiters are too dense to allow the radio emission to escape from the planets.
1365-2966
3505–3517
Weber, C.
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Lammer, H.
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Shaikhislamov, I. F.
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Chadney, Joshua
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Khodachenko, M. L.
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Griessmeier, J.-M.
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Rucker, H. O.
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Vocks, C.
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Macher, W.
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Odert, P.
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Kislyakova, K. G.
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Weber, C.
536eecfe-bd31-47d2-832e-45b1496fb8b1
Lammer, H.
5357f0a5-8f44-4e3a-98a6-bda61e8253b3
Shaikhislamov, I. F.
9c52dc2c-c87f-40c3-98c6-64391ede1c7d
Chadney, Joshua
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Khodachenko, M. L.
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Griessmeier, J.-M.
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Rucker, H. O.
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Vocks, C.
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Macher, W.
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Odert, P.
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Kislyakova, K. G.
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Weber, C., Lammer, H., Shaikhislamov, I. F., Chadney, Joshua, Khodachenko, M. L., Griessmeier, J.-M., Rucker, H. O., Vocks, C., Macher, W., Odert, P. and Kislyakova, K. G. (2017) How expanded ionospheres of Hot Jupiters can prevent escape of radio emission generated by the cyclotron maser instability. Monthly Notices of the Royal Astronomical Society, 469 (3), 3505–3517. (doi:10.1093/mnras/stx1099).

Record type: Article

Abstract

We present a study of plasma conditions in the atmospheres of the Hot Jupiters HD 209458b and HD 189733b and for an HD 209458b like planet at orbit locations between 0.2 and 1 au around a Sun-like star. We discuss how these conditions influence the radio emission we expect from their magnetospheres. We find that the environmental conditions are such that the cyclotron maser instability (CMI), the process responsible for the generation of radio waves at magnetic planets in the Solar system, most likely will not operate at Hot Jupiters. Hydrodynamically expanding atmospheres possess extended ionospheres whose plasma densities within the magnetosphere are so large that the plasma frequency is much higher than the cyclotron frequency, which contradicts the condition for the production of radio emission and prevents the escape of radio waves from close-in exoplanets at distances <0.05 au from a Sun-like host star. The upper atmosphere structure of gas giants around stars similar to the Sun changes between 0.2 and 0.5 au from the hydrodynamic to a hydrostatic regime, and this results in conditions similar to Solar system planets with a region of depleted plasma between the exobase and the magnetopause, where the plasma frequency can be lower than the cyclotron frequency. In such an environment, a beam of highly energetic electrons accelerated along the field lines towards the planet can produce radio emission. However, even if the CMI could operate, the extended ionospheres of Hot Jupiters are too dense to allow the radio emission to escape from the planets.

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1706.06349 - Accepted Manuscript
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Accepted/In Press date: 3 May 2017
e-pub ahead of print date: 6 May 2017
Published date: 11 August 2017
Organisations: Astronomy Group

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Local EPrints ID: 411705
URI: http://eprints.soton.ac.uk/id/eprint/411705
ISSN: 1365-2966
PURE UUID: 3d789a87-8e9a-4dca-8985-f8f8fe5e2b59
ORCID for Joshua Chadney: ORCID iD orcid.org/0000-0002-5174-2114

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Date deposited: 22 Jun 2017 16:31
Last modified: 16 Mar 2024 05:28

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Contributors

Author: C. Weber
Author: H. Lammer
Author: I. F. Shaikhislamov
Author: Joshua Chadney ORCID iD
Author: M. L. Khodachenko
Author: J.-M. Griessmeier
Author: H. O. Rucker
Author: C. Vocks
Author: W. Macher
Author: P. Odert
Author: K. G. Kislyakova

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