453 research outputs found
Measurement of turbulent spatial structure and kinetic energy spectrum by exact temporal-to-spatial mapping
HAT-P-25b: a Hot-Jupiter Transiting a Moderately Faint G Star
We report the discovery of HAT-P-25b, a transiting extrasolar planet orbiting
the V = 13.19 G5 dwarf star GSC 1788-01237, with a period P = 3.652836 +/-
0.000019 days, transit epoch Tc = 2455176.85173 +/- 0.00047 (BJD), and transit
duration 0.1174 +/- 0.0017 days. The host star has mass of 1.01 +/- 0.03
M(Sun), radius of 0.96 +(0.05)-(0.04) R(Sun), effective temperature 5500 +/- 80
K, and metallicity [Fe/H] = +0.31 +/- 0.08. The planetary companion has a mass
of 0.567 +/- 0.022 M(Jup), and radius of 1.190 +(0.081)-(0.056) R(Jup) yielding
a mean density of 0.42 +/- 0.07 g cm-3. Comparing these observations with
recent theoretical models, we find that HAT-P-25b is consistent with a
hydrogen-helium dominated gas giant planet with negligible core mass and age
3.2 +/- 2.3 Gyr. The properties of HAT-P-25b support several previously
observed correlations for planets in the mass range 0.4 < M < 0.7 M(Jup),
including those of core mass vs. metallicity, planet radius vs. equilibrium
temperature, and orbital period vs. planet mass. We also note that HAT-P-25b
orbits the faintest star found by HATNet to have a transiting planet to date,
and is one of only a very few number of planets discovered from the ground
orbiting a star fainter than V = 13.0.Comment: 11 pages, 8 figures, 5 tables, submitted to Ap
Constraining planet structure from stellar chemistry: the cases of CoRoT-7, Kepler-10, and Kepler-93
We explore the possibility that the stellar relative abundances of different
species can be used to constrain the bulk abundances of known transiting rocky
planets. We use high resolution spectra to derive stellar parameters and
chemical abundances for Fe, Si, Mg, O, and C in three stars hosting low mass,
rocky planets: CoRoT-7, Kepler-10, and Kepler-93. These planets follow the same
line along the mass-radius diagram, pointing toward a similar composition. The
derived abundance ratios are compared with the solar values. With a simple
stoichiometric model, we estimate the iron mass fraction in each planet,
assuming stellar composition. We show that in all cases, the iron mass fraction
inferred from the mass-radius relationship seems to be in good agreement with
the iron abundance derived from the host star's photospheric composition. The
results suggest that stellar abundances can be used to add constraints on the
composition of orbiting rocky planets.Comment: A&A Letters, in pres
Self-Enhancement of Dynamic Gratings in Photogalvanic Crystals
We have developed a compact closed-form solution of the band transport model for high-contrast gratings in photogalvanic crystals. Our solution predicts the effect of the photoconductivity and the electric field grating enhancement due to the photogalvanic effect. We predict a pronounced dependence of the steady-state photogalvanic current on the contrast of the interference pattern and an increase of holographic storage time due to the enhancement of the photoconductivity grating contrast. In the high contrast limit and a large photogalvanic effect the refractive index grating will be shifted from the position of the intensity modulation pattern, contrary to the usually adopted model of unshifted gratings
KIC 1571511B:a benchmark low-mass star in an eclipsing binary system in the <i>Kepler </i>field
Qatar Exoplanet Survey : Qatar-3b, Qatar-4b and Qatar-5b
We report the discovery of Qatar-3b, Qatar-4b, and Qatar-5b, three new
transiting planets identified by the Qatar Exoplanet Survey (QES). The three
planets belong to the hot Jupiter family, with orbital periods of
=2.50792 days, =1.80539 days, and =2.87923 days.
Follow-up spectroscopic observations reveal the masses of the planets to be
=4.31 , =6.10 , and
= 4.32 , while model fits to the transit light
curves yield radii of = 1.096 , =
1.135 , and = 1.107 . The
host stars are low-mass main sequence stars with masses and radii =
1.145 , = 0.896 ,
= 1.128 and = 1.272 ,
= 0.849 and = 1.076
for Qatar-3, 4 and 5 respectively. The V magnitudes of the three
host stars are =12.88, =13.60, and =12.82. All three
new planets can be classified as heavy hot Jupiters (M > 4 ).Comment: 13Pages, 8Figure
HAT-P-56b: An inflated massive Hot Jupiter transiting a bright F star followed up with K2 Campaign 0 observations
We report the discovery of HAT-P-56b by the HATNet survey, an inflated hot
Jupiter transiting a bright F type star in Field 0 of NASA's K2 mission. We
combine ground-based discovery and follow-up light curves with high precision
photometry from K2, as well as ground-based radial velocities from TRES on the
FLWO 1.5m telescope to determine the physical properties of this system.
HAT-P-56b has a mass of , radius of , and transits its host
star on a near-grazing orbit with a period of 2.7908 d. The radius of HAT-P-56b
is among the largest known for a planet with . The host star has a
V-band magnitude of 10.9, mass of 1.30 , and radius of 1.43 .
The periodogram of the K2 light curve suggests the star is a Dor
variable. HAT-P-56b is an example of a ground-based discovery of a transiting
planet, where space-based observations greatly improve the confidence in the
confirmation of its planetary nature, and also improve the accuracy of the
planetary parameters.Comment: 13 pages, 11 figures, accepted by A
Qatar-1b: a hot Jupiter orbiting a metal-rich K dwarf star
We report the discovery and initial characterisation of Qatar-1b, a hot
Jupiter orbiting a metal-rich K dwarf star, the first planet discovered by the
Alsubai Project exoplanet transit survey. We describe the strategy used to
select candidate transiting planets from photometry generated by the Alsubai
Project instrument. We examine the rate of astrophysical and other false
positives found during the spectroscopic reconnaissance of the initial batch of
candidates. A simultaneous fit to the follow-up radial velocities and
photometry of Qatar-1b yield a planetary mass of 1.09+/-0.08 Mjup and a radius
of 1.16+/-0.05 Rjup. The orbital period and separation are 1.420033 days and
0.0234 AU for an orbit assumed to be circular. The stellar density, effective
temperature and rotation rate indicate an age greater than 4 Gyr for the
system.Comment: 8 pages, 5 figures, submitted to Monthly Notices of the Royal
Astronomical Societ
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