Georgia Mraz, Antoine Darveau-Bernier, Anne Boucher, Nicolas B. Cowan, David Lafrenière, Charles Cadieux
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引用次数: 0
摘要
我们利用加拿大-法国-夏威夷望远镜上的 SpectroPolarimètre InfraRouge 观测了超热木星 WASP-33b。之前对 WASP-33b 日面的观测显示,有证据表明 CO 和 Fe 辐射表明存在热反转。我们对其夜面进行了五个地球之夜的观测,以寻找该行星热辐射中的 CO 光谱特征。我们的三次凌日前观测和两次凌日后观测分别对早晨或傍晚终结点附近的区域非常敏感。通过光谱检索,我们在该行星过境后的发射光谱中探测到了∼6.6σ处的CO分子吸收。这是对一颗系外行星夜间热辐射的最强地基探测,也是有史以来的第三次探测。吸收中出现的一氧化碳表明,傍晚终结者附近的夜侧没有温度反转;如果日侧的反转是由恒星辐射吸收驱动的,这就说得通了。相反,我们没有探测到来自早晨终结者的一氧化碳。这可能与向东喷流的热吸力一致。相位分辨高分辨率光谱法为研究短周期系外行星的垂直和水平大气温度曲线提供了一种经济的替代方法,而不是基于空间的全轨道光谱相位曲线。
Out of the Darkness: High-resolution Detection of CO Absorption on the Nightside of WASP-33b
We observed the ultrahot Jupiter WASP-33b with the SpectroPolarimètre InfraRouge on the Canada–France–Hawaii Telescope. Previous observations of the dayside of WASP-33b show evidence of CO and Fe emission indicative of a thermal inversion. We observed its nightside over five Earth nights to search for spectral signatures of CO in the planet’s thermal emission. Our three pretransit observations and two posttransit observations are sensitive to regions near the morning or evening terminators, respectively. From spectral retrievals, we detect CO molecular absorption in the planet’s emission spectrum after transit at ∼6.6σ. This is the strongest ground-based detection of nightside thermal emission from an exoplanet and only the third ever. CO appearing in absorption suggests that the nightside near the evening terminator does not have a temperature inversion; this makes sense if the dayside inversion is driven by absorption of stellar radiation. On the contrary, we do not detect CO from the morning terminator. This may be consistent with heat advection by an eastward jet. Phase-resolved high-resolution spectroscopy offers an economical alternative to space-based full-orbit spectroscopic phase curves for studying the vertical and horizontal atmospheric temperature profiles of short-period exoplanets.