31 research outputs found
The MIRC-X 6-telescope imager: Key science drivers, instrument design and operation
This is the final version of the article. Available from SPIE via the DOI in this recordMIRC-X is a new beam combination instrument at the CHARA array that enables 6-telescope interferometric imaging on object classes that until now have been out of reach for milliarcsecond-resolution imaging. As part of an instrumentation effort lead by the University of Exeter and University of Michigan, we equipped the MIRC instrument with an ultra-low read-noise detector system and extended the wavelength range to the J and H-band. The first phase of the MIRC-X commissioning was successfully completed in June 2017. In 2018 we will commission polarisation control to improve the visibility calibration and implement a 'cross-talk resiliant' mode that will minimise visibility cross-talk and enable exoplanet searches using precision closure phases. Here we outline our key science drivers and give an overview about our commissioning timeline. We comment on operational aspects, such as remote observing, and the prospects of co-phased parallel operations with the upcoming MYSTIC combiner.MIRC-X is funded by a Starting Grant from the European Research Council (ERC; grant agreement No. 639889,
PI: Kraus) and funds from the University of Exeter. The project builds on earlier investments from the University
of Michigan and the National Science Foundation (NSF, PI: Monnier)
Multiple spiral arms in the disk around intermediate-mass binary HD 34700A
This is the final version. Available from American Astronomical Society / IOP Publishing via the DOI in this record.We present the first images of the transition disk around the close binary system HD 34700A in
polarized scattered light using the Gemini Planet Imager instrument on Gemini South. The J and H
band images reveal multiple spiral-arm structures outside a large (R = 0.4900 = 175 au) cavity along
with a bluish spiral structure inside the cavity. The cavity wall shows a strong discontinuity and
we clearly see significant non-azimuthal polarization Uφ consistent with multiple scattering within a
disk at an inferred inclination ∼42◦
. Radiative transfer modeling along with a new Gaia distance
suggest HD 37400A is a young (∼5 Myr) system consisting of two intermediate-mass (∼2 M ) stars
surrounded by a transitional disk and not a solar-mass binary with a debris disk as previously classified.
Conventional assumptions of the dust-to-gas ratio would rule out a gravitational instability origin to the
spirals while hydrodynamical models using the known external companion or a hypothetical massive
protoplanet in the cavity both have trouble reproducing the relatively large spiral arm pitch angles
(∼ 30◦
) without fine tuning of gas temperature. We explore the possibility that material surrounding
a massive protoplanet could explain the rim discontinuity after also considering effects of shadowing
by an inner disk. Analysis of archival Hubble Space Telescope data suggests the disk is rotating
counterclockwise as expected from the spiral arm structure and revealed a new low-mass companion at
6.4500separation. We include an appendix which sets out clear definitions of Q, U, Qφ, Uφ, correcting
some confusion and errors in the literature.Science and Technology Facilities CouncilEuropean Research CouncilNASANational Science Foundation (NSF)University of Colorado Boulder Hale Fellowship progra
Probing the Inner Disk Emission of the Herbig Ae Stars HD 163296 and HD 190073
This is the author accepted manuscript. The final version is available from American Astronomical Society / IOP Publishing via the DOI in this record.The physical processes occurring within the inner few astronomical units of proto-planetary disks surrounding Herbig Ae stars are crucial to setting the environment in which the outer planet-forming disk evolves and put critical constraints on the processes of accretion and planet migration. We present the most complete published sample of high angular resolution H- and K-band observations of the stars HD 163296 and HD 190073, including 30 previously unpublished nights of observations of the former and 45 nights of the latter with the CHARA long-baseline interferometer, in addition to archival VLTI data. We confirm previous observations suggesting significant near-infrared emission originates within the putative dust evaporation front of HD 163296 and show this is the case for HD 190073 as well. The H- and K-band sizes are the same within (3±3)% for HD 163296 and within (6±10)% for HD 190073. The radial surface brightness profiles for both disks are remarkably Gaussian-like with little or no sign of the sharp edge expected for a dust evaporation front. Coupled with spectral energy distribution analysis, our direct measurements of the stellar flux component at H and K bands suggest that HD 190073 is much younger (<400 kyr) and more massive (~5.6 M⊙) than previously thought, mainly as a consequence of the new Gaia distance (891 pc).JDM and BRS acknowledge support from NSF-AST 1506540 and AA acknowledges support from NSF-AST 1311698.
CLD, AK, and SK acknowledge support from the ERC Starting Grant “ImagePlanetFormDiscs” (Grant Agreement
No. 639889), STFC Rutherford fellowship/grant (ST/J004030/1, ST/K003445/1) and Philip Leverhulme Prize (PLP2013-110).
FB acknowledges support from NSF-AST 1210972 and 1445935. MS acknowledges support by the NASA
Origins of Solar Systems grant NAG5-9475, and NASA Astrophysics Data Program contract NNH05CD30C. The CHARA Array is supported by the National Science Foundation under Grant No. AST-1211929, AST-1636624,
and AST-1715788. Institutional support has been provided from the GSU College of Arts and Sciences and the GSU
Office of the Vice President for Research and Economic Development
Dynamical masses of the primary Be star and the secondary sdB star in the single-lined binary kappa Dra (B6 IIIe)
Because many classical Be stars may owe their nature to mass and
angular-momentum transfer in a close binary, the present masses, temperatures,
and radii of their components are of high interest for comparison to stellar
evolution models. Kappa Dra is a 61.5-day single-lined binary with a B6 IIIe
primary. With the CHARA Array instruments MIRC/MIRC-X and MYSTIC, we detected
the secondary at (approximately photospheric) flux ratios of 1.49 +- 0.10% and
1.63 +- 0.09% in the H and K band, respectively. From a large and diverse
optical spectroscopic database only the radial velocity curve of the Be star
could be extracted. However, employing the parallaxes from Hipparcos and Gaia,
which agree within their nominal 1-sigma errors, we could derive the total mass
and found component masses of 3.65 +- 0.48 Msun and 0.426 +- 0.043 Msun for the
Be star and the companion, respectively. Previous cross-correlation of the
observed far-UV spectrum with sdO spectral model templates had not detected a
companion belonging to the hot O-type subdwarf (sdO) population known from ~20
earlier-type Be stars. Guided by our full 3D orbital solution, we found a
strong cross-correlation signal for a stripped subdwarf B-type companion
(far-UV flux ratio of 2.3 +- 0.5%), enabling the first firm characterization of
such a star, and making kappa Dra the first mid- to late-type Be star with a
directly-observed subdwarf companion.Comment: Accepted to ApJ. Figure sets available on reques
MYSTIC: a high angular resolution K-band imager at CHARA
This is the final version. Available from SPIE via the DOI in this recordSPIE Astronomical Telescopes + Instrumentation 2022, 17 - 22 July 2022, Montreal, CanadaThe Michigan Young STar Imager at CHARA (MYSTIC) is a K-band interferometric beam combining instrument funded by the United States National Science Foundation, designed primarily for imaging sub-au scale disk structures around nearby young stars and to probe the planet formation process. Installed at the CHARA array in July 2021, with baselines up to 331 meters, MYSTIC provides a maximum angular resolution of λ/2B ∼ 0.7 mas. The instrument injects phase corrected light from the array into inexpensive, single-mode, polarization maintaining silica fibers, which are then passed via a vacuum feedthrough into a cryogenic dewar operating at 220 K for imaging. MYSTIC utilizes a high frame rate, ultra-low read noise SAPHIRA detector, and implements two beam combiners: a 6-telescope image plane beam combiner, based on the MIRC-X design, for targets as faint as 7.7 Kmag, as well as a 4-telescope integrated optic beam-combiner mode using a spare chip leftover from the GRAVITY instrument. MYSTIC is co-phased with the MIRC-X (J+H band) instrument for simultaneous fringe-tracking and imaging, and shares its software suite with the latter to allow a single observer to operate both instruments. Herein, we present the instrument design, review its operational performance, present early commissioning science observations, and propose upgrades to the instrument that could improve its K-band sensitivity to 10th magnitude in the near future.National Science Foundation (NSF)European Union Horizon 2020NASAEuropean Research Council (ERC)Science and Technology Facilities Council (STFC
The Orbits and Dynamical Masses of the Castor System
This is the final version. Available on open access from the American Astronomical Society via the DOI in this recordCastor is a system of six stars in which the two brighter objects, Castor A and B, revolve around each other every ∼450 yr and are both short-period spectroscopic binaries. They are attended by the more distant Castor C, which is also a binary. Here we report interferometric observations with the Center for High Angular Resolution Astronomy (CHARA) array that spatially resolve the companions in Castor A and B for the first time. We complement these observations with new radial velocity measurements of A and B spanning 30 yr, with the Hipparcos intermediate data, and with existing astrometric observations of the visual AB pair obtained over the past three centuries. We perform a joint orbital solution to solve simultaneously for the three-dimensional orbits of Castor A and B as well as the AB orbit. We find that they are far from being coplanar: the orbit of A is nearly at right angles (92°) relative to the wide orbit, and that of B is inclined about 59° compared to AB. We determine the dynamical masses of the four stars in Castor A and B to a precision better than 1%. We also determine the radii of the primary stars of both subsystems from their angular diameters measured with the CHARA array, and use them together with stellar evolution models to infer an age for the system of 290 Myr. The new knowledge of the orbits enables us to measure the slow motion of Castor C as well, which may assist future studies of the dynamical evolution of this remarkable sextuple system.European Research Council (ERC)Science and Technology Facilities Council (STFC
MYSTIC: a high angular resolution K-band imager at CHARA
This is the final version. Available on open access from SPIE via the DOI in this recordData, Materials, and Code Availability:
The data reduction pipeline is available at https://gitlab.chara.gsu.edu/lebouquj/mircx_pipeline/Much of this manuscript originally appeared in SPIE Proceedings Volume 12183, Optical and Infrared Interferometry and Imaging VIII; 121830B (2022) https://doi.org/10.1117/12.2629437; available in ORE at http://hdl.handle.net/10871/131161The Michigan Young Star Imager at CHARA (MYSTIC) is a K-band interferometric beam combining instrument funded by the U.S. National Science Foundation, designed primarily for imaging sub-au scale disk structures around nearby young stars and to probe the planet formation process. Installed at the CHARA Array in July 2021, with baselines up to 331 m, MYSTIC provides a maximum angular resolution of λ / 2B ∼ 0.7 mas. The instrument injects phase-corrected light from the array into inexpensive, single-mode, polarization maintaining silica fibers, which are then passed via a vacuum feedthrough into a cryogenic dewar operating at 220 K for imaging. MYSTIC uses a high frame rate, ultra-low read noise SAPHIRA detector and implements two beam combiners: a six-telescope image plane beam combiner, based on the MIRC-X design, for targets as faint as 7.7 Kmag, as well as a four-telescope integrated optic beam-combiner mode using a spare chip leftover from the GRAVITY instrument. MYSTIC is co-phased with the MIRC-X (J + H band) instrument for simultaneous fringe-tracking and imaging and shares its software suite with the latter to allow a single observer to operate both instruments. We present the instrument design, review its operational performance, present early commissioning science observations, and propose upgrades to the instrument that could improve its K-band sensitivity to 10th magnitude in the near future.USA National Science Foundation Advanced Technologies and Instrumentation ProgramEuropean Union Horizon 2020NASA-XRPNSF-ASTNASA-MSGCNASAEuropean Research Council (ERC)Science and Technology Facilities Council (STFC
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Scattering and sublimation: a multi-scale view of µm-sized dust in the inclined disc of HD 145718
This is the final version. Available from Oxford University Press via the DOI in this recordData availability: The GPI data are available from the Gemini Observatory Archive at https://archive.gemini.edu/searchform and can be accessed using proposal number GS-2018A-LP-12. The MIRC-X data will be made available through the OiDB (http://oidb.jmmc.fr) following publication. VLTI/GRAVITY and VLTI/PIONIER data are available in the ESO archive (http://archive.eso.org/ cms.html) and the OiDB and can be accessed using the target name ‘HD 145718’. The photometry are accessible through SEDBYS,available at https://gitlab.com/clairedavies/sedbys. The IR spectra are available in the IRSA (https://irsa.ipac. caltech.edu).We present multi-instrument observations of the disc around the Herbig Ae star, HD 145718, employing geometric and Monte Carlo radiative transfer models to explore the disc orientation, the vertical and radial extent of the near infrared (NIR) scattering surface, and the properties of the dust in the disc surface and sublimation rim. The disc appears inclined at 67−71◦, with position angle, PA= −1.0 − 0.6◦, consistent with previous estimates. The NIR scattering surface extends out to ∼ 75au and we infer an aspect ratio, hscat(r)/r ∼ 0.24 in J-band; ∼ 0.22 in H-band. Our GPI images and VLTI+CHARA NIR interferometry suggest that the disc surface layers are populated by grains λ/2π in size, indicating these grains are aerodynamically supported against settling and/or the density of smaller grains is relatively low. We demonstrate that our geometric analysis provides a reasonable assessment of the height of the NIR scattering surface at the outer edge of the disc and, if the inclination can be independently constrained, has the potential to probe the flaring exponent of the scattering surface in similarly inclined (i 70◦) discs. In re-evaluating HD 145718’s stellar properties, we found that the object’s dimming events -previously characterised as UX Or and dipper variability -are consistent with dust occultation by grains larger, on average, than found in the ISM. This occulting dust likely originates close to the inferred dust sublimation radius at 0.17au.European CommissionUniversity of ExeterNational Science Foundation (NSF)Science and Technology Facilities Council (STFC)NAS