An internal heating mechanism operating in ultra-short-period planets orbiting magnetically active stars

IF 27.8 1区 物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS
Antonino Francesco Lanza
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Abstract

A new mechanism for the internal heating of ultra-short-period planets is proposed based on the gravitational perturbation by a non-axisymmetric quadrupole moment of their host stars. Such a quadrupole is due to the magnetic flux tubes in the stellar convection zone, unevenly distributed in longitude and persisting for many stellar rotations as observed in young late-type stars. The rotation period of the host star evolves from its shortest value on the zero-age main sequence to longer periods due to the loss of angular momentum through a magnetized wind. If the stellar rotation period comes close to twice the orbital period of the planet, the quadrupole leads to a spin-orbit resonance that excites oscillations of the star-planet separation. As a consequence, a strong tidal dissipation is produced inside the planet. We illustrate the operation of the mechanism by modeling the evolution of the stellar rotation and of the innermost planetary orbit in the cases of CoRoT-7, Kepler-78, and K2-141 whose present orbital periods range between 0.28 and 0.85 days. If the spin-orbit resonance occurs, the maximum power dissipated inside the planets ranges between $10^{18}$ and $10^{19}$ W, while the total dissipated energy is of the order of $10^{30}-10^{32}$ J over a time interval as short as $(1-4.5) \times 10^{4}$ yr. Such a huge heating over a so short time interval produces a complete melting of the planetary interiors and may shut off their hydromagnetic dynamos. These may initiate a successive phase of intense internal heating owing to unipolar magnetic star-planet interactions and affect the composition and the escape of their atmospheres, producing effects that could be observable during the entire lifetime of the planets [abridged abstract].
超短周期行星运行的内部加热机制
基于宿主恒星非轴对称四极矩的引力摄动,提出了超短周期行星内部加热的新机制。这种四极是由于恒星对流区的磁通管,在经度上分布不均匀,并且在年轻的晚型恒星中观察到许多恒星旋转时持续存在。主星的旋转周期从零年龄主序上的最短值演变为更长的周期,这是由于磁化风造成角动量的损失。如果恒星的自转周期接近行星轨道周期的两倍,四极子就会导致自旋轨道共振,从而激发恒星-行星分离的振荡。因此,在行星内部产生了强烈的潮汐耗散。我们通过模拟CoRoT-7、Kepler-78和K2-141的恒星旋转和最内层行星轨道的演变来说明这一机制的运作,它们目前的轨道周期在0.28到0.85天之间。如果发生自旋轨道共振,行星内部耗散的最大功率在$10^{18}$和$10^{19}$ W之间,而耗散的总能量为$10^{30}- $10^{32}$ J,时间间隔短至$(1-4.5)× 10^{4}$ yr。如此巨大的加热在如此短的时间间隔内会使行星内部完全熔化,并可能关闭它们的磁发电机。由于单极磁性恒星与行星的相互作用,这可能会引发一个连续的强烈内部加热阶段,并影响其大气的组成和逸出,产生的影响在行星的整个生命周期中都可以观察到。
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来源期刊
The Astronomy and Astrophysics Review
The Astronomy and Astrophysics Review 地学天文-天文与天体物理
CiteScore
45.00
自引率
0.80%
发文量
7
期刊介绍: The Astronomy and Astrophysics Review is a journal that covers all areas of astronomy and astrophysics. It includes subjects related to other fields such as laboratory or particle physics, cosmic ray physics, studies in the solar system, astrobiology, instrumentation, and computational and statistical methods with specific astronomical applications. The frequency of review articles depends on the level of activity in different areas. The journal focuses on publishing review articles that are scientifically rigorous and easily comprehensible. These articles serve as a valuable resource for scientists, students, researchers, and lecturers who want to explore new or unfamiliar fields. The journal is abstracted and indexed in various databases including the Astrophysics Data System (ADS), BFI List, CNKI, CNPIEC, Current Contents/Physical, Chemical and Earth Sciences, Dimensions, EBSCO Academic Search, EI Compendex, Japanese Science and Technology, and more.
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