Incorporating Inner Magnetosphere Current-driven Electron Acceleration in Numerical Simulations of Exoplanet Radio Emission

Sciola, Anthony; Toffoletto, F.; Alexander, David; Sorathia, Kareem; Merkin, V. G.; Farrish, A.

doi:10.3847/1538-4357/abefd9

Cited by 7 publications

(11 citation statements)

References 65 publications

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“…Nichols & Milan (2016) applied the concept of ionospheric saturation, well observed and parameterized at Earth (Reiff et al 1981;Weimer et al 1990;Hairston et al 2005;Ridley 2005;Siscoe 2011), to the typical environment of hot Jupiters, and found that the energy available for CMI emission from the Region 1 current system may be up to several orders of magnitude lower than what the RBL predicts. Sciola et al (2021) performed numerical MHD simulations of an Earth-like planet under extreme saturation conditions (separate from the simulation shown here) and found that the emission power produced by these primary FACs calculated by the analytic model and numerical simulation are in good agreement. However, Sciola et al (2021) also found that FACs generated via secondary wind-magnetosphere coupling processes, which map to lower magnetic latitudes, can drive significantly stronger CMI emission under the right stellar wind conditions (i.e., strong variability).…”

Section: Emission Latitudesmentioning

confidence: 81%

“…Sciola et al (2021) performed numerical MHD simulations of an Earth-like planet under extreme saturation conditions (separate from the simulation shown here) and found that the emission power produced by these primary FACs calculated by the analytic model and numerical simulation are in good agreement. However, Sciola et al (2021) also found that FACs generated via secondary wind-magnetosphere coupling processes, which map to lower magnetic latitudes, can drive significantly stronger CMI emission under the right stellar wind conditions (i.e., strong variability). These secondary processes are highly coupled and nonlinear and must be resolved with a numerical MHD model, which is impossible to perform for the entire set of exoplanets considered in this study.…”

Section: Emission Latitudesmentioning

confidence: 81%

“…A thorough overview of the subject can be found in the reviews by Zarka et al (2015a) and Grießmeier (2015. Starting with the foundational theoretical studies (Winglee et al 1986;Zarka et al 1997;Farrell et al 1999;Zarka et al 2001;Zarka 2007) a large body of theoretical work has been published (e.g., de Pater 2000; Farrell et al 2004;Lazio et al 2004;Grießmeier et al , 2007aGrießmeier et al , 2007bStevens 2005;Jardine & Cameron 2008;Vidotto et al 2010Vidotto et al , 2012Vidotto et al , 2015Vidotto et al , 2019Hess & Zarka 2011;Nichols 2011Nichols , 2012See et al 2015;Fujii et al 2016;Nichols & Milan 2016;Vidotto & Donati 2017;Weber et al 2017aWeber et al , 2017bWeber et al , 2018Lynch et al 2018;Zarka 2018;Kavanagh et al 2019;Wang & Loeb 2019;de Gasperin et al 2020;Shiohira et al 2020;Hori 2021;Narang et al 2021;Sciola et al 2021;Cendes et al 2022). The goals of these studies are to predict the frequency of emission and the radio flux observed from Earth.…”

Section: Introductionmentioning

confidence: 99%

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Detecting Magnetospheric Radio Emission from Giant Exoplanets

Ashtari

Sciola

Turner

et al. 2022

ApJ

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As radio astronomy enters a golden age, ground-based observatories are reaching sensitivities capable of unlocking a new and exciting field of exoplanet observation. Radio observation of planetary auroral emission provides unique and complementary insight into planetary science not available via orthodox exoplanet observation techniques. Supplying the first measurements of planetary magnetic fields, rotation rates, and orbital obliquities, we gain necessary and crucial insight into our understanding of the star–planet relationships, geophysics, composition, and habitability of exoplanets. Using a stellar-wind-driven Jovian approximation, we present analytical methods for estimating magnetospheric radio emission from confirmed exoplanets. Predicted radio fluxes from cataloged exoplanets are compared against the wavelengths and sensitivities of current and future observatories. Candidate exoplanets are downselected based on the sky coverage of each ground-based observatory. Orbits of target exoplanets are modeled to account for influential orbit-dependent effects in anticipating time-varying exoplanet radio luminosity and flux. To evaluate the angular alignment of exoplanetary beamed emission relative to Earth’s position, the equatorial latitude of exoplanetary auroral emission is compared against Earth’s apparent latitude on the exoplanet. Predicted time-dependent measurements and recommended beamformed observations for ground-based radio arrays are provided, along with a detailed analysis of the anticipated emission behavior for τ Boo b.

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Section: Emission Latitudesmentioning

confidence: 81%

Section: Emission Latitudesmentioning

confidence: 81%

Section: Introductionmentioning

confidence: 99%

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Detecting Magnetospheric Radio Emission from Giant Exoplanets

Ashtari

Sciola

Turner

et al. 2022

ApJ

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“…However, the auroral radio emission mentioned above is influenced by the ionosphere, resulting in potentially observable ionospheric effects. The modulating effects of the ionosphere must be taken into account for predicting or analyzing observations of auroral radio emission (Sciola et al, 2021). Radio emission may only be observable under certain planetary and astrospheric conditions, but testing models on observable planets will provide key constraints and validation of our models.…”

Section: Exoplanet Ionospheresmentioning

confidence: 99%

“…Even in the case of supersonic stellar winds, the conditions can be so extreme that the magnetopause boundary is close to the planetary surface (Dong et al, 2017b;Slavin et al, 2019). This also presents significant numerical challenges because the larger intrinsic wave speeds in the region of the stronger magnetic field near the planet require a much smaller timestep for numerical stability, making the computations quite expensive (e.g., Sciola et al, 2021). The adaptation of sophisticated heliophysics models for exoplanet applications requires acknowledgment of areas where we are missing basic physics in our models and so may help us to better understand the limitations of our knowledge, to better define our computational needs, and to incorporate new or different physics in the models.…”

Section: Modeling Opportunities and Challengesmentioning

confidence: 99%

Star-exoplanet interactions: A growing interdisciplinary field in heliophysics

Garcia‐Sage

Farrish²,

Airapetian³

et al. 2023

Front. Astron. Space Sci.

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Traditionally, heliophysics is characterized as the study of the near-Earth space environment, where plasmas and neutral gases originating from the Earth, the Sun, and other solar system bodies interact in ways that are detectable only through in-situ or close-range (usually within ∼10 AU) remote sensing. As a result, heliophysics has data from the space environment around a handful of solar system objects, in particular the Sun and Earth. Comparatively, astrophysics has data from an extensive array of objects, but is more limited in temporal, spatial, and wavelength information from any individual object. Thus, our understanding of planetary space environments as a complex, multi-dimensional network of specific interacting systems may in the past have seemed to have little to do with the highly diverse space environments detected through astrophysical methods. Recent technological advances have begun to bridge this divide. Exoplanetary studies are opening up avenues to study planetary environments beyond our solar system, with missions like Kepler, TESS, and JWST, along with increasing capabilities of ground-based observations. At the same time, heliophysics studies are pushing beyond the boundaries of our heliosphere with Voyager, IBEX, and the future IMAP mission.The interdisciplinary field of star-exoplanet interactions is a critical, growing area of study that enriches heliophysics. A multidisciplinary approach to heliophysics enables us to better understand universal processes that operate in diverse environments, as well as the evolution of our solar system and extreme space weather. The expertise, data, theory, and modeling tools developed by heliophysicists are crucial in understanding the space environments of exoplanets, their host stars, and their potential habitability. The mutual benefit that heliophysics and exoplanetary studies offer each other depends on strong, continuing solar system-focused and Earth-focused heliophysics studies. The heliophysics discipline requires new targeted funding to support inter-divisional opportunities, including small multi-disciplinary research projects, large collaborative research teams, and observations targeting the heliophysics of planetary and exoplanet systems. Here we discuss areas of heliophysics-relevant exoplanetary research, observational opportunities and challenges, and ways to promote the inclusion of heliophysics within the wider exoplanetary community.

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