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

Weber, Christof; Lämmer, H.; Шайхисламов, И. Ф.; Chadney, Joshua; Khodachenko, M. L.; Grießmeier, Jean-Mathias; Rücker, H. O.; Vocks, C.; Macher, W.; Odert, P.; Kislyakova, K. G.

doi:10.1093/mnras/stx1099

Cited by 66 publications

(66 citation statements)

References 70 publications

(197 reference statements)

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“…The five to ten fold higher magnetic field we predict from our analysis may be able to change the plasma conditions around HJs to such an extent that radio emission may escape. To quantify the changes, more analysis similar to Weber et al (2017) should be carried out for HJs with the higher magnetic fields we predict.…”

Section: Summary and Discussionmentioning

confidence: 99%

Estimating the Magnetic Field Strength in Hot Jupiters

Yadav

Thorngren

2017

ApJL

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A large fraction of known Jupiter like exoplanets are inflated as compared to Jupiter. These "hot" Jupiters orbit close to their parent star and are bombarded with intense starlight. Many theories have been proposed to explain their radius inflation and several suggest that a small fraction of the incident starlight is injected in to the planetary interior which helps to puff up the planet. How will such energy injection affect the planetary dynamo? In this Letter, we estimate the surface magnetic field strength of hot Jupiters using scaling arguments that relate energy available in planetary interiors to the dynamo generated magnetic fields. We find that if we take into account the energy injected in the planetary interior that is sufficient to inflate hot Jupiters to observed radii, then the resulting dynamo should be able generate magnetic fields that are more than an order of magnitude stronger than the Jovian values. Our analysis highlights the potential fundamental role of the stellar light in setting the field strength in hot Jupiters.

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Section: Summary and Discussionmentioning

confidence: 99%

Estimating the Magnetic Field Strength in Hot Jupiters

Yadav

Thorngren

2017

ApJL

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“…The right‐hand sides of Equations and reduce down to constants such that the resultant units are in MHz. For the emission process to be efficient, this ratio needs to be ≳ 2.5 (Weber et al ). In the following section, this ratio for the circumplanetary material of both models and discussed in the context of observational emission will be shown.…”

Section: Modelingmentioning

confidence: 99%

Interacting fields and flows: Magnetic hot Jupiters

Daley-Yates

Stevens

2017

Astron Nachr

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We present magnetohydrodynamic (MHD) simulations of the magnetic interactions between a solar‐type star and short‐period hot Jupiter exoplanets using the publicly available MHD code PLUTO. It has been predicted that emission due to magnetic interactions such as the electron cyclotron maser instability (ECMI) will be observable. In our simulations, a planetary outflow, due to UV evaporation of the exoplanets atmosphere, results in the build‐up of circumplanetary material. We predict the ECMI emission and determine that the emission is prevented from escaping the system. This is due to the evaporated material leading to a high plasma frequency in the vicinity of the planet, which inhibits the ECMI process.

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“…It is the FUV and X-ray heating of the upper exosphere that results in temperatures an order of magnitude higher (Lammer et al 2003) than the effective temperature. This enhancement of the exosphere temperature is directly responsible for the hydrodynamic atmospheric expansion seen in multiple HJs (Lammer et al 2003;Weber et al 2017;Sairam et al 2018). Enhanced mass-loss is not the only a consequence of absorbed stellar radiation.…”

Section: Planetary Fuv Evaporationmentioning

confidence: 99%

“…Values of the order 50 G are predicted by Yadav & Thorngren (2017), an order of magnitude larger than Jupiter's magnetic field. However, such field strengths would be detectable due to MHz radio emission via the Electron Cyclotron Maser Instability (ECMI) (Weber et al 2017;Daley-Yates & Stevens 2017.…”

Section: Planetary Fuv Evaporationmentioning

confidence: 99%

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Hot Jupiter accretion: 3D MHD simulations of star–planet–wind interaction

Daley-Yates

Stevens

2018

Monthly Notices of the Royal Astronomical Society

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We present 3D MHD simulations of the wind-wind interactions between a solar type star and a short period hot Jupiter exoplanet. This is the first such simulation in which the stellar surface evolution is studied in detail. In our simulations, a planetary outflow, based on models of FUV evaporation of the exoplanets upper atmosphere, results in the build-up of circumstellar and circumplanetary material which accretes onto the stellar surface in a form of coronal rain, in which the rain is HJ wind material falling onto the stellar surface. We have conducted a suite of mixed geometry high resolution simulations which characterise the behaviour of interacting stellar and planetary wind material for a representative HJ hosting system. Our results show that magnetic topology plays a central role in forming accretion streams between the star and HJ and that the nature of the accretion is variable both in location and in rate, with the final accretion point occurring at φ = 227 • ahead of the sub-planetary point and θ = 53 • below the orbital plain. The size of the accretion spot itself has been found to vary with a period of 67 ks. Within the accretion spot, there is a small decrease in temperature accompanied by an increase in density compared with ambient surface conditions. We also demonstrate that magnetic fields cannot be ignored as accretion is highly dependent upon the magnetic topology of both the HJ and the host. We characterise this behaviour as Star Planet Wind Interaction (SPWI).

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

Cited by 66 publications

References 70 publications

Estimating the Magnetic Field Strength in Hot Jupiters

Estimating the Magnetic Field Strength in Hot Jupiters

Interacting fields and flows: Magnetic hot Jupiters

Hot Jupiter accretion: 3D MHD simulations of star–planet–wind interaction

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