56 research outputs found
K2 reveals pulsed accretion driven by the 2 Myr old hot Jupiter CI Tau b
CI Tau is a young (~2 Myr) classical T Tauri star located in the Taurus star
forming region. Radial velocity observations indicate it hosts a Jupiter-sized
planet with an orbital period of approximately 9 days. In this work, we analyze
time series of CI Tau's photometric variability as seen by K2. The lightcurve
reveals the stellar rotation period to be ~6.6 d. Although there is no evidence
that CI Tau b transits the host star, a ~9 d signature is also present in the
lightcurve. We believe this is most likely caused by planet-disk interactions
which perturb the accretion flow onto the star, resulting in a periodic
modulation of the brightness with the ~9 d period of the planet's orbit.Comment: Accepted for publication in ApJ Letter
Magnetic field strengths of hot Jupiters from signals of star-planet interactions
Evidence of star-planet interactions in the form of planet-modulated
chromospheric emission has been noted for a number of hot Jupiters. Magnetic
star-planet interactions involve the release of energy stored in the stellar
and planetary magnetic fields. These signals thus offer indirect detections of
exoplanetary magnetic fields. Here we report the derivation of the magnetic
field strengths of four hot Jupiter systems using the power observed in Ca II K
emission modulated by magnetic star-planet interactions. By approximating the
fractional energy released in the Ca II K line we find that the surface
magnetic field values for the hot Jupiters in our sample range from 20 G to 120
G, ~10-100 times larger than the values predicted by dynamo scaling laws for
planets with rotation periods of ~2 - 4 days. On the other hand, these value
are in agreement with scaling laws relating the magnetic field strength to the
internal heat flux in giant planets. Large planetary magnetic field strengths
may produce observable electron-cyclotron maser radio emission by preventing
the maser from being quenched by the planet's ionosphere. Intensive radio
monitoring of hot Jupiter systems will help confirm these field values and
inform on the generation mechanism of magnetic fields in this important class
of exoplanets.Comment: Published 7/22/2019 in Nature Astronomy:
https://www.nature.com/articles/s41550-019-0840-x. 20 pages, 3 figures, 3
tables, 3 supplementary figures, 1 supplementary tabl
Searching for spectroscopic binaries within transition disk objects
S.A. Kohn acknowledges the support of NSF REU grant AST-1004107 through Northern Arizona University and Lowell Observatory. J. Llama acknowledges support from NASA Origins of the Solar System grant No. NNX13AH79G and from STFC grant ST/M001296/1. This research made use of the SIMBAD database, operated at CDS, Strasbourg, France.Transition disks (TDs) are intermediate stage circumstellar disks characterized by an inner gap within the disk structure. To test whether these gaps may have been formed by closely orbiting, previously undetected stellar companions, we collected high-resolution optical spectra of 31 TD objects to search for spectroscopic binaries (SBs). Twenty-four of these objects are in Ophiuchus and seven are within the Coronet, Corona Australis, and Chameleon I star-forming regions. We measured radial velocities for multiple epochs, obtaining a median precision of 400 ms−1. We identified double-lined SB SSTc2d J163154.7–250324 in Ophiuchus, which we determined to be composed of a K7(±0.5) and a K9(±0.5) star, with orbital limits of a < 0.6 au and P < 150 days. This results in an SB fraction of in Ophiuchus, which is consistent with other spectroscopic surveys of non-TD objects in the region. This similarity suggests that TDs are not preferentially sculpted by the presence of close binaries and that planet formation around close binaries may take place over similar timescales to that around single stars.Publisher PDFPeer reviewe
Amplitude modulation of short-timescale hot spot variability
Funding Information: L.I.B., L.A.P., and J.L. acknowledge support from NASA through an Astrophysics Data Analysis Program grant to Lowell Observatory (grant 80NSSC20K1001). A.C.C. and M.M.J. acknowledge support from the Science and Technology Facilities Council (STFC) consolidated grant No. ST/R00824/1, and the support of the visiting scientist program at Lowell Observatory in 2019 January and 2020 January. Data were obtained using the Mikulski Archive for Space Telescopes (MAST). STScI is operated by the Association of Universities for Research in Astronomy, Inc., under NASA contract NAS5-26555.Variability of Classical T Tauri stars (CTTS) occurs over a vast range of timescales. CTTS in particular are subject to variability caused by accretion shocks, which can occur stochastically, periodically, or quasi-periodically on timescales over a few days. The detectability of young planets within these systems is likely hampered by activity; therefore, it is essential that we understand the origin of young star variability over a range of timescales to help disentangle stellar activity from signatures of planetary origin. We present an analysis of the stochastic small-amplitude photometric variability in the K2 lightcurve of CI Tau occurring on timescales of ≲1 day. We find the amplitude of this variability exhibits the same periodic signatures as detected in the large-amplitude variability, indicating that the physical mechanism modulating these brightness features is the same. The periods detected are also in agreement with the rotation period of the star (∼6.6 days) and the orbital period of the planet (∼9.0 days) known to drive pulsed accretion onto the star.PostprintPeer reviewe
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Understanding the origins of stellar radio emission can provide invaluable
insight into the strength and geometry of stellar magnetic fields and the
resultant space weather environment experienced by exoplanets. Here, we present
the first model capable of predicting radio emission through the electron
cyclotron maser instability using observed stellar magnetic maps of low-mass
stars. We determine the structure of the coronal magnetic field and plasma
using spectropolarimetric observations of the surface magnetic fields and the
X-ray emission measure. We then model the emission of photons from the
locations within the corona that satisfy the conditions for electron cyclotron
maser emission. Our model predicts the frequency, and intensity of radio
photons from within the stellar corona.
We have benchmarked our model against the low-mass star V374 Peg. This star
has both radio observations from the Very Large Array and a nearly simultaneous
magnetic map. Using our model we are able to fit the radio observations of V374
Peg, providing additional evidence that the radio emission observed from
low-mass stars may originate from the electron cyclotron maser instability. Our
model can now be extended to all stars with observed magnetic maps to predict
the expected frequency and variability of stellar radio emission in an effort
to understand and guide future radio observations of low-mass stars.Comment: Accepted for publication in Ap
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