Hot-Jupiters are a class of planets that orbit very close to
their host stars. As a result, these planets receive extremely intense
irradiation and are expected to be tidally-locked, with one side experiencing
permanent day and one side experiencing permanent night. The strong temperature
contrast between the permanent day and night sides on a hot-Jupiter drives a
powerful west-to-east circulation that goes around the planet.
If the orbit of the hot-Jupiter is observed edge-on, it will
appear to pass behind its host star on every orbit. Such an event is known as
an eclipse. The planet’s evening-side is more visible pre-eclipse (i.e. during
the first half of the orbit), while the planet’s morning-side is more visible
post-eclipse (i.e. during the second half of the orbit). As the planet circles
around its host star, some fraction of its illuminated hemisphere will be
visible depending on the position of the planet in its orbit. This generates a
light curve where the combined brightness of the star and planet varies in a
small and periodic fashion every orbit. The variation is small because the star
is orders of magnitude brighter than the planet.
Figure 1: Artist’s impression of a hot-Jupiter that is glowing
red hot.
Using data from NASA’s Kepler space telescope, a study by
Esteves et al. (2015) uncovered weather cycles on 6 hot-Jupiters. The brightest
spot on each planet appears offset from the substellar point. Basically, the
substellar point on a hot-Jupiter is the spot on the planet where the planet’s
host star is directly overhead and it is where the stellar irradiation is most
intense. The 2 hotter planets (Kepler-76b and HAT-P-7b) appear brightest
pre-eclipse (i.e. the brightest spot on the planet is east of the substellar
point, towards the evening-side); while the 4 cooler planets (Kepler-7b,
Kepler-8b, Kepler-12b and Kepler-41b) appear brightest post-eclipse (i.e. the
brightest spot on the planet is west of the substellar point, towards the
morning-side).
On these 6 hot-Jupiters, winds blow eastward from the
substellar point towards the evening-side, around the night side and back
towards the morning-side, before returning to the substellar point. The 4
cooler planets (Kepler-7b, Kepler-8b, Kepler-12b and Kepler-41b) all have
temperatures under ~2,300 K. The best explanation why they appear brightest on
the morning-side (i.e. post-eclipse) is because cool temperatures on the night
side allow clouds to form by condensation and the west-to-east atmospheric
circulation brings these reflective clouds to the morning-side, causing the
morning-side to be the brightest region on the planet. Subsequently, these
clouds continue on towards the substellar point where they dissipate due to the
increased irradiation.
In contrasts, the 2 hotter planets (Kepler-76b and HAT-P-7b)
have temperatures exceeding ~2,700 K and both planets appear brightest on the
evening-side (i.e. pre-eclipse). The best explanation is that the brightness is
dominated by thermal emission from a hot-spot that has been shifted east from
the substellar point, towards the evening-side. Furthermore, the high
temperatures make it difficult for clouds to form, resulting in little or no
clouds on the morning-side that can reflect a sufficient amount of incoming stellar
radiation to contribute significantly to the planet’s brightness.
For the 4 cooler planets, the brightest spot is shifted west
(i.e. towards the morning-side) from the substellar point by over ~25° since
the clouds are probably thickest and most reflectively near the day-night
terminator on the morning-side. For the 2 hotter planets, the brightest spot is
shifted by a much smaller amount of less than ~8°, this time the shift is
eastwards (i.e. towards the evening-side). The brightest spot is closer to the substellar
point for the 2 hotter planets due to the rapid re-emission of absorbed stellar
energy after leaving the substellar point. This study supports the correlation between
the position of a planet’s brightest spot and the planet’s temperature. The
brightness of a hotter planet is likely to be dominated by thermal emission
from a hot-spot that has been shifted east of the substellar point (i.e. evening-side),
while the brightness of a cooler planet is likely to be dominated by reflected
light from clouds west of the substellar point (i.e. morning-side).
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Figure 2: Light curve of Kepler-8b, a hot-Jupiter with 1.42
times the radius and 0.59 times the mass of Jupiter, in a 3.52-day orbit around
its host star. The left and right panels contain, respectively, the transit light
curve (i.e. drop in the star’s brightness when the planet passes in front of its
host star) and phase light curve (i.e. combined brightness of the star and
planet as the planet orbits the star). On the right panel, the dip in the middle denotes the eclipse, whereby the planet passes behind its host star and is obscured. Esteves et al. (2015).
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Figure 3: Light curve of Kepler-12b, a hot-Jupiter with 1.75
times the radius and 0.43 times the mass of Jupiter, in a 4.44-day orbit around
its host star. Esteves et al. (2015).
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Figure 4: Light curve of Kepler-41b, a hot-Jupiter with 1.04
times the radius and 0.56 times the mass of Jupiter, in a 1.86-day orbit around
its host star. Esteves et al. (2015).
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Figure 5: Light curve of Kepler-8b, a hot-Jupiter with 1.36
times the radius and 2.01 times the mass of Jupiter, in a 1.54-day orbit around
its host star. Esteves et al. (2015).
Reference:
Esteves et al. (2015), “Changing Phases of Alien Worlds:
Probing Atmospheres of Kepler Planets with High-Precision Photometry”, arXiv:1407.2245
[astro-ph.EP]