Spin Transitions and Compressibility of ε‐Fe
            7
            N
            3
            and γ′‐Fe
            4
            N: Implications for Iron Alloys in Terrestrial Planet Cores

ABSTRACT The paper analyses possible transfers of bodies from the main asteroid belt (MBA) to the Centaur region. The orbits of asteroids in the 2:1 mean motion resonance (MMR) with Jupiter are analysed. We selected the asteroids that are in resonant orbits with e > 0.3 whose absolute magnitudes H do not exceed 16 m. The total number of the orbits amounts to 152. Numerical calculations were performed to evaluate the evolution of the orbits over 100,000-year time interval with projects for the future. Six bodies are found to have moved from the 2:1 commensurability zone to the Centaur population. The transfer time of these bodies to the Centaur zone ranges from 4,600 to 70,000 yr. Such transfers occur after orbits leave the resonance and the bodies approach Jupiter Where after reaching sufficient orbital eccentricities bodies approach a terrestrial planet, their orbits go out of the MMR. Accuracy estimations are carried out to confirm the possible asteroid transfers to the Centaur region.

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Earth-size planet formation in the habitable zone of circumbinary stars

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa757 ◽

2020 ◽

Vol 494 (1) ◽

pp. 1045-1057 ◽

Cited By ~ 1

Author(s):

G O Barbosa ◽

O C Winter ◽

A Amarante ◽

A Izidoro ◽

R C Domingos ◽

...

Keyword(s):

Numerical Simulations ◽

Planet Formation ◽

Terrestrial Planet ◽

Close Binary ◽

Habitable Zone ◽

Density Profiles ◽

Habitable Planets ◽

Habitable Zones ◽

Test Particles ◽

The Stability

ABSTRACT This work investigates the possibility of close binary (CB) star systems having Earth-size planets within their habitable zones (HZs). First, we selected all known CB systems with confirmed planets (totaling 22 systems) to calculate the boundaries of their respective HZs. However, only eight systems had all the data necessary for the computation of HZ. Then, we numerically explored the stability within HZs for each one of the eight systems using test particles. From the results, we selected five systems that have stable regions inside HZs, namely Kepler-34,35,38,413, and 453. For these five cases of systems with stable regions in HZ, we perform a series of numerical simulations for planet formation considering discs composed of planetary embryos and planetesimals, with two distinct density profiles, in addition to the stars and host planets of each system. We found that in the case of the Kepler-34 and 453 systems, no Earth-size planet is formed within HZs. Although planets with Earth-like masses were formed in Kepler-453, they were outside HZ. In contrast, for the Kepler-35 and 38 systems, the results showed that potentially habitable planets are formed in all simulations. In the case of the Kepler-413system, in just one simulation, a terrestrial planet was formed within HZ.

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