The Habitability of Proxima Centauri b: Environmental States and Observational Discriminants

Meadows, Victoria; Arney, Giada; Schwieterman, Edward W.; Lustig‐Yaeger, Jacob; Lincowski, Andrew; Robinson, Tyler D.; Domagal-Goldman, Shawn; Deitrick, Russell; Barnes, Rory; Fleming, D. P.; Luger, Rodrigo; Driscoll, Peter; Quinn, Thomas; Crisp, David

doi:10.1089/ast.2016.1589

Cited by 142 publications

(206 citation statements)

References 254 publications

(556 reference statements)

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“…Turbet et al (2016) studied two likely rotation modes (tidally locked and 3:2 resonances) reaching the conclusion that, for both synchronous and non-synchronous rotation, there are scenarios which would allow liquid water to be present. Other studies have aimed at understanding the likely climate, photosynthetic properties and observational discriminants of the atmosphere of Proxima b (Goldblatt 2016;Lopez et al 2014;Meadows et al 2016;Kreidberg & Loeb 2016). We have shown here that space weather conditions of Proxima b are extreme and very different to those experienced on Earth.…”

Section: Resultsmentioning

confidence: 51%

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THE SPACE WEATHER OF PROXIMA CENTAURI b

Garraffo

Drake

Cohen

2016

ApJL

159

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A planet orbiting in the "habitable zone" of our closest neighboring star, Proxima Centauri, has recently been discovered, and the next natural question is whether or not Proxima b is"habitable". Stellar winds are likely a source of atmospheric erosion that could be particularly severe in the case of M dwarf habitable zone planets that reside close to their parent star. Here we study the stellar wind conditions that Proxima b experiences over its orbit. We construct 3-D MHD models of the wind and magnetic field around Proxima Centauri using a surface magnetic field map for a star of the same spectral type and scaled to match the observed ∼ 600 G surface magnetic field strength of Proxima. We examine the wind conditions and dynamic pressure over different plausible orbits that sample the constrained parameters of the orbit of Proxima b. For all the parameter space explored, the planet is subject to stellar wind pressures of more than 2000 times those experienced by Earth from the solar wind. During an orbit, Proxima b is also subject to pressure changes of 1 to 3 orders of magnitude on timescales of a day. Its magnetopause standoff distance consequently undergoes sudden and periodic changes by a factor of 2 to 5. Proxima b will traverse the interplanetary current sheet twice each orbit, and likely crosses into regions of subsonic wind quite frequently. These effects should be taken into account in any physically realistic assessment or prediction of its atmospheric reservoir, characteristics and loss.

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Section: Resultsmentioning

confidence: 51%

“…Apart from its approximate mass and orbital parameters, rather little is currently known about Proxima b itself, although a handful of studies have already examined its likely irradiation history and possible climate and evolution in relation to potential habitability Turbet et al 2016;Barnes et al 2016;Meadows et al 2016). …”

Section: Introductionmentioning

confidence: 99%

THE SPACE WEATHER OF PROXIMA CENTAURI b

Garraffo

Drake

Cohen

2016

ApJL

159

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“…By constraining the planet's formation and migration history, high-energy irradiance, incoming stellar particle winds, and tidal interactions, along with the host star's evolution history, one can estimate the planet's atmospheric loss rate, its water budget, and its overall climate regime (Ribas et al 2016;Turbet et al 2016). Barnes et al (2016b) and Meadows et al (2016) demonstrate that a planet's geologic behavior can be constrained by modeling its orbit evolution and tidal history, as well as heavy element abundances in the planets core. Such works provide possible next steps toward characterizing the nature of exoplanets in early-type systems.…”

Section: Climate Effectsmentioning

confidence: 99%

Gravity-Darkened Seasons: Insolation Around Rapid Rotators

Ahlers

2016

ApJ

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I model the effect of rapid stellar rotation on a planet's insolation. Fast-rotating stars have induced pole-to-equator temperature gradients (known as gravity-darkening) of up to several thousand Kelvin that affect the star's luminosity and peak emission wavelength as a function of latitude. When orbiting such a star, a planet's annual insolation can strongly vary depending on its orbit inclination. Specifically, inclined orbits result in temporary exposure to the star's hotter poles. I find that gravity-darkening can drive changes in a planet's equilibrium temperature of up to ∼ 15% due to increased irradiance near the stellar poles. This effect can also vary a planet's exposure to UV radiation by up to ∼ 80% throughout its orbit as it is exposed to an irradiance spectrum corresponding to different stellar effective temperatures over time.

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“…Consequently, in advance of larger diameter ground-and space-based telescopes, and improvements in visible AO systems, we must initially consider observations that do not rely on transits or current coronagraphy to search for and characterize the atmosphere of Proxima Cen b. Phase curves may offer one of the first means to study the atmosphere of Proxima Cen b Kreidberg & Loeb 2016;Meadows et al 2016) by potentially showing the reduction in day-night thermal emission contrast associated with an atmosphere. Phase curves have proven to be a successful means to characterize the atmospheres of planets larger and hotter than Proxima Cen b Knutson et al 2007; Knutson et al 2008;Crossfield et al 2010;Brogi et al 2012;Zellem et al 2014;Stevenson et al 2014), including ones that do not transit (Selsis et al 2011;Faigler & Mazeh 2011;Maurin et al 2012;Brogi et al 2014).…”

Section: Introductionmentioning

confidence: 99%

“…Since the Proxima system is only 1.3pc away, it is perhaps the best-case scenario for the detection of the faint auroral signal from a terrestrial exoplanet. Even though the planet-star contrast ratio in reflected visible light is poor ( 10 −7 ; see Turbet et al 2016;Kreidberg & Loeb 2016;Meadows et al 2016), if Proxima Cen b exhibits auroral emission, this will brighten the planet and potentially boost the planet-star contrast by one or more orders of magnitude at the wavelengths of the auroral emission features. The short wavelength of the oxygen green line also improves the contrast of the planet relative to the star due to the star's cool temperature and TiO absorption, which strongly suppresses the brightness of the star in the visible.…”

Section: Introductionmentioning

confidence: 99%

The Pale Green Dot: A Method to Characterize Proxima Centauri b Using Exo-Aurorae

Luger

Lustig‐Yaeger

Fleming

et al. 2017

ApJ

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We examine the feasibility of detecting auroral emission from the potentially habitable exoplanet Proxima Centauri b. Detection of aurorae would yield an independent confirmation of the planet's existence, constrain the presence and composition of its atmosphere, and determine the planet's eccentricity and inclination, thereby breaking the mass-inclination degeneracy. If Proxima Centauri b is a terrestrial world with an Earth-like atmosphere and magnetic field, we estimate the power at the 5577Å OI auroral line is on the order of 0.1 TW under steady-state stellar wind, or ∼100× stronger than that on Earth. This corresponds to a planet-star contrast ratio of 10 −6 − 10 −7 in a narrow band about the 5577Å line, although higher contrast (10 −4 − 10 −5 ) may be possible during periods of strong magnetospheric disturbance (auroral power 1 − 10 TW). We searched the Proxima Centauri b HARPS data for the 5577Å line and for other prominent oxygen and nitrogen lines, but find no signal, indicating that the OI auroral line contrast must be lower than 2 × 10 −2 (with power 3,000 TW), consistent with our predictions. We find that observations of 0.1 TW auroral emission lines are likely infeasible with current and planned telescopes. However, future observations with a space-based coronagraphic telescope or a ground-based extremely large telescope (ELT) with a coronagraph could push sensitivity down to terawatt oxygen aurorae (contrast 7 × 10 −6 ) with exposure times of ∼1 day. If a coronagraph design contrast of 10 −7 can be achieved with negligible instrumental noise, a future concept ELT could observe steady-state auroral emission in a few nights.

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The Habitability of Proxima Centauri b: Environmental States and Observational Discriminants

Cited by 142 publications

References 254 publications

THE SPACE WEATHER OF PROXIMA CENTAURI b

THE SPACE WEATHER OF PROXIMA CENTAURI b

Gravity-Darkened Seasons: Insolation Around Rapid Rotators

The Pale Green Dot: A Method to Characterize Proxima Centauri b Using Exo-Aurorae

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