Kaloyan Penev, L G Bouma, Joshua N Winn, Joel D Hartman
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引用次数: 44
摘要
拥有热木星的恒星往往比其他年龄和质量相同的恒星旋转得更快。这种趋势归因于恒星和行星之间的潮汐相互作用。对耗散参数Q -百科的约束来自于这样的假设:在系统的年龄范围内,潮汐已经成功地使恒星旋转到观测到的速率。该技术先前应用于HATS-18和WASP-19。在这里,我们分析了所有188颗已知的热木星的样本,这些热木星的轨道周期为3.5天,有一颗“冷”的主恒星(T eff 6100K)。我们发现有证据表明,潮汐耗散参数(Q -教员)随强迫频率急剧增加,从0.5 d -1时的105增加到2 d -1时的107。这有助于解决双星、热木星和暖木星中潮汐耗散研究之间的一些明显差异。它也可能允许热木星在被潮汐衰变摧毁之前降低其主星的倾角。
EMPIRICAL TIDAL DISSIPATION IN EXOPLANET HOSTS FROM TIDAL SPIN-UP.
Stars with hot Jupiters tend to be rotating faster than other stars of the same age and mass. This trend has been attributed to tidal interactions between the star and planet. A constraint on the dissipation parameter follows from the assumption that tides have managed to spin up the star to the observed rate within the age of the system. This technique was applied previously to HATS-18 and WASP-19. Here we analyze the sample of all 188 known hot Jupiters with an orbital period <3.5 days and a "cool" host star (Teff< 6100K). We find evidence that the tidal dissipation parameter increases sharply with forcing frequency, from 105 at 0.5 day-1 to 107 at 2 day-1. This helps to resolve a number of apparent discrepancies between studies of tidal dissipation in binary stars, hot Jupiters, and warm Jupiters. It may also allow for a hot Jupiter to damp the obliquity of its host star prior to being destroyed by tidal decay.
期刊介绍:
The Astronomical Journal publishes original astronomical research, with an emphasis on significant scientific results derived from observations. Publications in AJ include descriptions of data capture, surveys, analysis techniques, astronomical interpretation, instrumentation, and software and computing.
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