Rapid Formation of Gas Giant Planets around M Dwarf Stars

AbstractM dwarf stars are attractive targets in the search for habitable worlds as a result of their relative abundance and proximity, making them likely targets for future direct detection efforts. Hot super-Earths as well as gas giants have already been detected around a number of early M dwarfs, and the former appear to be the high-mass end of the population of rocky, terrestrial exoplanets. The Carnegie Astrometric Planet Search (CAPS) program has been underway since March 2007, searching ~ 100 nearby late M, L, and T dwarfs for gas giant planets on orbits wide enough for habitable worlds to orbit interior to them. The CAPSCam-N camera on the 2.5-m du Pont telescope at the Las Campanas Observatory has demonstrated the ability to detect planets as low in mass as Saturn orbiting at several AU around late M dwarfs within 15 pc. Over the next decade, the CAPS program will provide new constraints on the planetary census around late M dwarf stars, and hence on the suitability of these nearby planetary systems for supporting life.

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Rapid Formation of Super-Earths around M Dwarf Stars

The Astrophysical Journal ◽

10.1086/505533 ◽

2006 ◽

Vol 644 (1) ◽

pp. L79-L82 ◽

Cited By ~ 54

Author(s):

Alan P. Boss

Keyword(s):

Dwarf Stars ◽

Rapid Formation ◽

M Dwarf Stars ◽

M Dwarf

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Searches for Brown Dwarfs

International Astronomical Union Colloquium ◽

10.1017/s025292110002649x ◽

1994 ◽

Vol 147 ◽

pp. 463-480

Author(s):

James Liebert

Keyword(s):

Brown Dwarfs ◽

Giant Planets ◽

Dwarf Stars ◽

Substellar Objects ◽

M Dwarf Stars ◽

M Dwarf

AbstractThis review attempts a brief summary of the numerous and diverse searches for the so-called brown dwarfs, substellar objects having masses between giant planets and the lowest mass M dwarf stars.

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Rapid Formation of Gas-giant Planets via Collisional Coagulation from Dust Grains to Planetary Cores

The Astrophysical Journal ◽

10.3847/1538-4357/ac289c ◽

2021 ◽

Vol 922 (1) ◽

pp. 16

Author(s):

Hiroshi Kobayashi ◽

Hidekazu Tanaka

Keyword(s):

Protoplanetary Disks ◽

Central Star ◽

Giant Planets ◽

Solar Systems ◽

Evolution Path ◽

Planetary Cores ◽

Rapid Formation ◽

Gas Giant ◽

Planetary Migration ◽

Gas Accretion

Abstract Gas-giant planets, such as Jupiter, Saturn, and massive exoplanets, were formed via the gas accretion onto the solid cores, each with a mass of roughly 10 Earth masses. However, rapid radial migration due to disk–planet interaction prevents the formation of such massive cores via planetesimal accretion. Comparably rapid core growth via pebble accretion requires very massive protoplanetary disks because most pebbles fall into the central star. Although planetesimal formation, planetary migration, and gas-giant core formation have been studied with a lot of effort, the full evolution path from dust to planets is still uncertain. Here we report the result of full simulations for collisional evolution from dust to planets in a whole disk. Dust growth with realistic porosity allows the formation of icy planetesimals in the inner disk (≲10 au), while pebbles formed in the outer disk drift to the inner disk and there grow to planetesimals. The growth of those pebbles to planetesimals suppresses their radial drift and supplies small planetesimals sustainably in the vicinity of cores. This enables rapid formation of sufficiently massive planetary cores within 0.2–0.4 million years, prior to the planetary migration. Our models shows the first gas giants form at 2–7 au in rather common protoplanetary disks, in agreement with the exoplanet and solar systems.

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An Astrobiological Experiment to Explore the Habitability of Tidally Locked M-Dwarf Planets

Proceedings of the International Astronomical Union ◽

10.1017/s1743921313012817 ◽

2012 ◽

Vol 8 (S293) ◽

pp. 192-196

Author(s):

Daniel Angerhausen ◽

Haley Sapers ◽

Eugenio Simoncini ◽

Stefanie Lutz ◽

Marcelo da Rosa Alexandre ◽

...

Keyword(s):

Academic Research ◽

Environmental Parameters ◽

Climate Simulation ◽

Habitable Zone ◽

Dwarf Stars ◽

Dwarf Planets ◽

Late Type Star ◽

M Dwarf Stars ◽

M Dwarf ◽

Simulation Chamber

AbstractWe present a summary of a three-year academic research proposal drafted during the Sao Paulo Advanced School of Astrobiology (SPASA) to prepare for upcoming observations of tidally locked planets orbiting M-dwarf stars. The primary experimental goal of the suggested research is to expose extremophiles from analogue environments to a modified space simulation chamber reproducing the environmental parameters of a tidally locked planet in the habitable zone of a late-type star. Here we focus on a description of the astronomical analysis used to define the parameters for this climate simulation.

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Coronal Structure in M Dwarf Stars

Magnetodynamic Phenomena in the Solar Atmosphere ◽

10.1007/978-94-009-0315-9_16 ◽

1996 ◽

pp. 81-82

Author(s):

M. S. Giampapa ◽

R. Rosner ◽

V. Kashyap ◽

T. A. Fleming ◽

J. H. M. M. Schmitt ◽

...

Keyword(s):

Coronal Structure ◽

Dwarf Stars ◽

M Dwarf Stars ◽

M Dwarf

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The habitability of stagnant-lid Earths around dwarf stars

Astronomy and Astrophysics ◽

10.1051/0004-6361/201834658 ◽

2019 ◽

Vol 625 ◽

pp. A12 ◽

Cited By ~ 8

Author(s):

Mareike Godolt ◽

Nicola Tosi ◽

Barbara Stracke ◽

John Lee Grenfell ◽

Thomas Ruedas ◽

...

Keyword(s):

Water Loss ◽

Main Sequence ◽

Extrasolar Planets ◽

Water Reservoir ◽

Habitable Zone ◽

High Luminosity ◽

Dwarf Stars ◽

Surface Conditions ◽

M Dwarf Stars ◽

M Dwarf

Context. The habitability of a planet depends on various factors, such as the delivery of water during its formation, the co-evolution of the interior and the atmosphere, and the stellar irradiation which changes in time. Aims. Since an unknown number of rocky extrasolar planets may operate in a one-plate convective regime, i.e. without plate tectonics, our aim is to understand the conditions under which planets in such a stagnant-lid regime may support habitable surface conditions. Understanding the interaction of the planetary interior and outgassing of volatiles in combination with the evolution of the host star is crucial to determining the potential habitability. M-dwarf stars in particular possess a high-luminosity pre-main sequence phase that endangers the habitability of planets around them via water loss. We therefore explore the potential of secondary outgassing from the planetary interior to rebuild a water reservoir allowing for habitability at a later stage. Methods. We compute the boundaries of the habitable zone around M-, K-, G-, and F-dwarf stars using a 1D cloud-free radiative-convective climate model accounting for the outgassing history of CO2 and H2O from an interior evolution and outgassing model for different interior compositions and stellar luminosity evolutions. Results. The outer edge of the habitable zone strongly depends on the amount of CO2 outgassed from the interior, while the inner edge is mainly determined via the stellar irradiation, as soon as a sufficiently large water reservoir has been outgassed. A build-up of a secondary surface and atmospheric water reservoir for planets around M-dwarf stars is possible even after severe water loss during the high-luminosity pre-main sequence phase as long as some water has been retained within the mantle. For small mantle water reservoirs, between 62 and 125 ppm, a time delay in outgassing from the interior permits such a secondary water reservoir build-up especially for early and mid-M dwarfs because their pre-main sequence lifetimes are shorter than the outgassing timescale. Conclusions. We show that Earth-like stagnant-lid planets allow for habitable surface conditions within a continuous habitable zone that is dependent on interior composition. Secondary outgassing from the interior may allow for habitability of planets around M-dwarf stars after severe water loss during the high-luminosity pre-main sequence phase by rebuilding a surface water reservoir.

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