Your search keyword '"astrometry"' showing total 880 results

1. Orbits and masses in two triple systems.

Author

Nazor, Dinko and Tokovinin, Andrei

Subjects

*ORBITS (Astronomy), *ACCELERATION (Mechanics), *BINARY stars, *PHOTOMETRY, *ASTROMETRY

Abstract

In an effort to determine accurate orbital and physical properties of a large number of bright stars, a method was developed to fit simultaneously stellar parameters (masses, luminosities, effective temperatures), distance, and orbits to the available data on multiple systems, namely the combined and differential photometry, positional measurements, radial velocities (RVs), accelerations, etc. The method is applied to a peculiar resolved triple system HIP 86286. The masses of its components estimated using observations and standard relations are 1.3, 0.9, and 0.9 |$M_\odot$|⁠ ; the main star is a G8IV subgiant, while its two companions are main-sequence dwarfs. The inner and outer orbital periods are 35 and 287 yr, respectively, and the orbits are nearly coplanar. The second system, HIP 117258, is an accelerating star with a resolved companion; its 35.7-yr orbit based on relative astrometry and precise RVs yields the secondary mass of 0.95 |$M_\odot$|⁠ , much larger than inferred from the photometry. The apparent paradox is explained by assuming that the secondary is a close pair of M-type dwarfs with yet unknown period. [ABSTRACT FROM AUTHOR]

Published

2024

2. Ultraviolet extinction correlation with 3D dust maps using white dwarfs.

Author

Sahu, Snehalata, Tremblay, Pier-Emmanuel, Lallement, Rosine, Redfield, Seth, and Gänsicke, Boris T

Subjects

*MAIN sequence (Astronomy), *ASTROMETRY, *INTERSTELLAR medium, *SPACE telescopes, *GALACTIC evolution, *WHITE dwarf stars, *STELLAR magnetic fields

Abstract

Accurate astrometric and photometric measurements from Gaia have led to the construction of 3D dust extinction maps which can now be used for estimating the integrated extinctions of Galactic sources located within 5 kpc. These maps based on optical observations may not be reliable for use in the ultraviolet (UV) which is more sensitive to reddening. Past studies have focussed on studying UV extinction using main-sequence stars but lack comparison with 3D dust maps. White dwarfs with well-modelled hydrogen-dominated (DA) atmospheres provide an advantage over main-sequence stars affected by magnetic activity. In this work, we study the variation of UV extinction with 3D dust maps utilizing Hubble Space Telescope (HST) and Galaxy Evolution Explorer (GALEX) observations of DA white dwarfs located within 300 pc. We used HST COS spectroscopic data of 76 sightlines to calculate the optical extinction from Si  ii column densities and validate our results with the kinematic model predictions of the local interstellar medium. Also, we combined GALEX and Gaia photometric observations of 1158 DA white dwarfs to study UV reddening by comparing observed and modelled colour–colour relations. We calculated GALEX non-linearity corrections and derived reddening coefficients [ |$R(NUV-G)=6.52\pm 1.53$| and |$R(FUV-G)=6.04\pm 2.41$| ] considering their variations with optical extinction (⁠|$\rm{A_{V}}\lt 0.1$|  mag), and found them to be in good agreement with known extinction laws. HST analysis suggests a positive bias of 0.01–0.02 mag in the optical extinction from 3D maps depending on the Galactic latitude. These results independently confirm the validity of 3D dust maps to de-redden the optical and UV observations of white dwarfs. [ABSTRACT FROM AUTHOR]

Published

2024

3. HD 28185 revisited: an outer planet, instead of a brown dwarf, on a Saturn-like orbit.

Author

Venner, Alexander, An, Qier, Huang, Chelsea X, Brandt, Timothy D, Wittenmyer, Robert A, and Vanderburg, Andrew

Subjects

*SOLAR system, *GAS giants, *NATURAL satellites, *OUTER planets, *BROWN dwarf stars, *INNER planets

Abstract

As exoplanet surveys reach ever-higher sensitivities and durations, planets analogous to the Solar system giant planets are increasingly within reach. HD 28185 is a Sun-like star known to host a |$m\sin i=6~M_\mathrm{ J}$| planet on an Earth-like orbit; more recently, a brown dwarf with a more distant orbit has been claimed. In this work, we present a comprehensive re-analysis of the HD 28185 system, based on 22 yr of radial velocity (RV) observations and precision Hipparcos–Gaia astrometry. We confirm the previous characterization of HD 28185 b as a temperate giant planet, with its |$385.92^{+0.06}_{-0.07}$| d orbital period giving it an Earth-like incident flux. In contrast, we substantially revise the parameters of HD 28185 c; with a new mass of |$m=6.0\pm 0.6~M_\mathrm{ J}$|⁠ , we reclassify this companion as a super-Jovian planet. HD 28185 c has an orbital period of |$24.9^{+1.3}_{-1.1}$| yr, a semimajor axis of |$8.50^{+0.29}_{-0.26}$| au, and a modest eccentricity of |$0.15\pm 0.04$|⁠ , resulting in one of the most Saturn-like orbits of any known exoplanet. HD 28185 c lies at the current intersection of detection limits for RVs and direct imaging, and highlights how the discovery of giant planets at |$\approx$| 10 au separations is becoming increasingly routine. [ABSTRACT FROM AUTHOR]

Published

2024

4. The DESI Early Data Release white dwarf catalogue.

Author

Manser, Christopher J, Izquierdo, Paula, Gänsicke, Boris T, Swan, Andrew, Koester, Detlev, Robert, Akshay, Xu, Siyi, Inight, Keith, Amroota, Ben, Fusillo, N P Gentile, Koposov, Sergey E, Kim, Bokyoung, Dey, Arjun, Prieto, Carlos Allende, Aguilar, J, Ahlen, S, Blum, R, Brooks, D, Claybaugh, T, and Cooper, A P

Subjects

*DATA release, *DARK energy, *ASTRONOMICAL surveys, *MAGNETIC fields, *ASTROMETRY

Abstract

The Early Data Release (EDR) of the Dark Energy Spectroscopic Instrument (DESI) comprises spectroscopy obtained from 2020 December 14 to 2021 June 10. White dwarfs were targeted by DESI both as calibration sources and as science targets and were selected based on Gaia photometry and astrometry. Here, we present the DESI EDR white dwarf catalogue, which includes 2706 spectroscopically confirmed white dwarfs of which approximately 60 per cent have been spectroscopically observed for the first time, as well as 66 white dwarf binary systems. We provide spectral classifications for all white dwarfs, and discuss their distribution within the Gaia Hertzsprung–Russell diagram. We provide atmospheric parameters derived from spectroscopic and photometric fits for white dwarfs with pure hydrogen or helium photospheres, a mixture of those two, and white dwarfs displaying carbon features in their spectra. We also discuss the less abundant systems in the sample, such as those with magnetic fields, and cataclysmic variables. The DESI EDR white dwarf sample is significantly less biased than the sample observed by the Sloan Digital Sky Survey, which is skewed to bluer and therefore hotter white dwarfs, making DESI more complete and suitable for performing statistical studies of white dwarfs. [ABSTRACT FROM AUTHOR]

Published

2024

5. A Statistical, Photometric, and SED Analysis to Characterize the BSS Populations in Old Open Cluster: Berkeley 39.

Author

Sheikh, A H and Medhi, Biman J

Subjects

*ECLIPSING binaries, *SPECTRAL energy distribution, *LIGHT curves, *MACHINE learning, *ASTROMETRY

Abstract

We present a statistical, photometric, and spectral energy distribution (SED) analysis to characterize the blue straggler stars (BSSs) populations in the Galactic old open cluster Berkeley 39. Berkeley 39 is a 6.16 Gyr old open cluster located at a distance of 3.99 Kpc. Gaia DR3 astrometry data have been used to estimate the membership probabilities using ensemble-based unsupervised machine learning techniques. We identified 21 BSS candidates on the colour–magnitude diagram, with 19 of them being detected in the Swift /UVOT UVW2 filter. We analysed the radial surface density profile and examined the cluster dynamical states and mass segregation effect. The SEDs of 19 BSSs are constructed using multiwavelength data covering UV to IR wavelengths. A single-component SED is fitted successfully for 14 BSS candidates. We discovered hot companions in five BSS candidates. These hot companions have temperatures of approximately 14 000 to 23 000 K, radii ranging from 0.04 to 0.13 R |$_{\odot }$|⁠ , and luminosities ranging from 0.16 to 2.91 L |$_{\odot }$|⁠. Among these, three are most likely extremely low-mass white dwarfs (WDs) with masses around 0.17 to 0.18 M |$_{\odot }$|⁠ , and two are low-mass WDs with masses around 0.18 to 0.39 M |$_{\odot }$|⁠. This confirms that they are post-mass transfer (Case A or Case B) systems. We also investigated the variable characteristics of BSSs by analysing their light curves using data from TESS. Our analysis confirms that two BSSs identified as eclipsing binaries in Gaia DR3 are indeed eclipsing binaries. Additionally, one of the two eclipsing binary BSSs shows evidence of having hot companions, as indicated by the multiwavelength SEDs. [ABSTRACT FROM AUTHOR]

Published

2024

6. Wide-field optical tracking of LEO objects: Theoretical assessment and observing strategy.

Author

Buzzoni, Alberto

Subjects

*OPTICAL resolution, *SPACE surveillance, *OPTICAL sensors, *ANGULAR velocity, *ASTROMETRY

Abstract

• A comparative assessment of the "surveying" vs. "tracking" strategy is discussed, to reach a better inventory of the orbiting population at a certain epoch. • Objective criteria are outlined for a best trade-off between telescope field of viev (FOV), CCD/CMOS platescale, telescope aperture and exposure time in order to maximize target(s) detection and astrometry. • Counter-intuitive aspects are discussed, compared with a more classical "astronomical" approach, delving the inherent link between time-tag accuracy and resolving power of optical imagery to track LEO objects. The main technical and strategic aspects related to Space Surveillance and Tracking (SST) with optical sensors are set in context in this study to lead to an efficient inventory of the active satellites and un-cooperant space debris population at Low-Earth orbital regimes (LEO). In particular, special emphasis is devoted to the combined interplay between timing of observations, target illumination conditions, instrumental fine tuning and data acquisition mode (surveying vs. active tracking). At LEO altitudes, satellites are seen to cross the sky at very high angular velocity, in excess to 0.5–1.5 deg/sec, always making their positional measurements (and the inferred dynamical properties) a challenging task for ground telescopes. To this aim, objective criteria have to be identified for a best trade-off between instrument field of viev (FOV), CCD/CMOS platescale, telescope aperture and exposure time in order to maximize target(s) detection and reference grid of stars valuable for astrometry. Many counter-intuitive aspects are discussed in this regard, compared for instance with a more classical "astronomical" approach, delving in particular the widely recognized inherent link between time-tag accuracy and resolving power of optical imagery to track LEO objects. A number of tables and graphical plots are provided for practical use to the reader. [ABSTRACT FROM AUTHOR]

Published

2024

7. A millisecond pulsar position determined to 0.2 mas precision with VLBI.

Author

Ding, Hao, Deller, Adam T., Freire, Paulo C. C., and Petrov, Leonid

Abstract

Context. Precise millisecond pulsar (MSP) positions determined with very long baseline interferometry (VLBI) hold the key to building the connection between the kinematic and dynamic reference frames respectively used for VLBI and pulsar timing. A frame connection would provide an important pathway to examining the planetary ephemerides used in pulsar timing, and would potentially enhance the sensitivities of the pulsar timing arrays used to detect stochastic gravitational-wave background in the nano-Hz regime. Aims. We aim to significantly improve the precision of the VLBI-based MSP position (from >1 mas at present) by reducing the two dominant components in the positional uncertainty – the propagation-related uncertainty and the uncertainty resulting from the frequency-dependent core shifts of the reference sources. Methods. We introduce a new differential astrometry strategy called PINPT (Phase-screen Interpolation plus frequeNcy-dePendent core shifT correction; pronounced "pinpoint"), which entails the use of multiple calibrators observed at several widely separated frequencies. The strategy allows determination of the core shift and mitigates the impact of residual delay in the atmosphere. We implemented the strategy on PSR J2222-0137, an MSP that is well constrained astrometrically with VLBI and pulsar timing. Results. Using the PINPT strategy, we determined core shifts for four AGNs around PSR J2222-0137, and derived a VLBI-based pulsar position with uncertainties of 0.17 mas and 0.32 mas in Right Ascension and Declination, respectively, approaching the uncertainty level of the best-determined timing-based MSP positions. Additionally, incorporating the new observations into historical ones, we refined the pulsar proper motion and the parallax-based distance to the <10 µas yr-1 level and the subparsec level, respectively. Conclusions. The realization of the PINPT strategy promises a factor-of-five positional precision enhancement (over conventional VLBI astrometry) for all kinds of compact radio sources observed at <2 GHz, including most fast radio bursts. [ABSTRACT FROM AUTHOR]

Published

2024

8. Physical properties of trans-Neptunian object (143707) 2003 UY117 derived from stellar occultation and photometric observations.

Author

Kretlow, M., Ortiz, J. L., Desmars, J., Morales, N., Rommel, F. L., Santos-Sanz, P., Vara-Lubiano, M., Fernández-Valenzuela, E., Alvarez-Candal, A., Duffard, R., Braga-Ribas, F., Sicardy, B., Castro-Tirado, A., Fernández-García, E. J., Sánchez, M., Sota, A., Assafin, M., Benedetti-Rossi, G., Boufleur, R., and Camargo, J. I. B.

Abstract

Context. Trans-Neptunian objects (TNOs) are considered to be among the most primitive objects in our Solar System. Knowledge of their primary physical properties is essential for understanding their origin and the evolution of the outer Solar System. In this context, stellar occultations are a powerful and sensitive technique for studying these distant and faint objects. Aims. We aim to obtain the size, shape, absolute magnitude, and geometric albedo for TNO (143707) 2003 UY117. Methods. We predicted a stellar occultation by this TNO for 2020 October 23 UT and ran a specific campaign to investigate this event. We derived the projected profile shape and size from the occultation observations by means of an elliptical fit to the occultation chords. We also performed photometric observations of (143707) 2003 UY117 to obtain the absolute magnitude and the rotational period from the observed rotational light curve. Finally, we combined these results to derive the three-dimensional shape, volume-equivalent diameter, and geometric albedo for this TNO. Results. From the stellar occultation, we obtained a projected ellipse with axes of (282 ± 18) × (184 ± 32) km. The area-equivalent diameter for this ellipse is Deq,A = 228 ± 21 km. From our photometric R band observations, we derived an absolute magnitude of HV = 5.97 ± 0.07 mag using V − R = 0.46 ± 0.07 mag, which was derived from a V band subset of these data. The rotational light curve has a peak-to-valley amplitude of ∆m = 0.36 ± 0.13 mag. We find the most likely rotation period to be P = 12.376 ± 0.0033 hours. By combining the occultation with the rotational light curve results and assuming a triaxial ellipsoid, we derived axes of a × b × c = (332 ± 24) km × (216 ± 24) km × (180−24+28) km for this ellipsoid, and therefore a volume-equivalent diameter of Deq,V = 235 ± 25 km. Finally, the values for the absolute magnitude and for the area-equivalent diameter yield a geometric albedo of pV = 0.139 ± 0.027. [ABSTRACT FROM AUTHOR]

Published

2024

9. Polarization of active galactic nuclei with significant VLBI-Gaia displacements.

Author

Blinov, Dmitry and Arshinova, Arina

Abstract

Context. Numerous studies have reported significant displacements in the coordinates of active galactic nuclei (AGNs) between measurements using the very-long-baseline-interferometry (VLBI) technique and those obtained by the Gaia space observatory. There is consensus that these discrepancies do indeed manifest astrometrically resolved sub-components of AGNs rather than random measurement noise. Among other evidence, it has been reported that AGNs with VLBI-to-Gaia displacements (VGDs) pointing downstream of their parsec-scale radio jets exhibit higher optical polarization compared to sources with the opposite (upstream) VGD orientation. Aims. We aim to verify the previously reported connection between optical polarization and a VGD-jet angle using a larger dataset of polarimetric measurements and updated Gaia DR3 positions. We also seek further evidence supporting the disk-jet dichotomy as an explanation of such a connection by using millimeter-wave polarization and multiband optical polarization measurements. Methods. We performed optical polarimetric observations of 152 AGNs using three telescopes. These data are complemented by other publicly available polarimetric measurements of AGNs. We cross-matched public astrometric data from VLBI and Gaia experiments, obtained corresponding positional displacements, and combined this catalog with the polarimetric and jet direction data. Results. Active galactic nuclei with downstream VGDs are confirmed to have significantly higher optical fractional polarization than the upstream sample. At the same time, the millimeter-wavelength polarization of the two samples shows very similar distributions. Conclusions. Our results support the hypothesis that the VGDs pointing down the radio jet are likely caused by a component in the jet emitting highly polarized synchrotron radiation and dominating in the overall optical emission. The upstream-oriented VGDs are likely to be produced by the low-polarization emission of the central engine's subcomponents, which dominate in the optical. [ABSTRACT FROM AUTHOR]

Published

2024

10. Analysis of the Gaia Data Release 3 parallax bias in the Galactic plane.

Author

Ding, Ye, Liao, Shilong, Wu, Qiqi, Qi, Zhaoxiang, and Tang, Zhenghong

Abstract

Context. Systematic errors are inevitable in Gaia published astrometric data. A global recipe has been proposed to correct for the GEDR3 parallax zero-point offset, but this does not take the Galactic plane into consideration. The applicability of their correction model to the Galactic plane remains uncertain. Aims. We attempt to carry out an independent investigation into the sample dependence of the proposed correction, and its applicability to the Galactic plane. Methods. We collected various samples, including quasars, binaries, and sources with parallaxes from other surveys or methods, to validate the proposed correction, especially in the Galactic plane. Results. We conclude that the proposed correction exhibits sample dependence, and does not apply effectively to the Galactic plane. We present a new parallax bias correction for application to the Galactic plane, offering improvements over the previous correction. The correction difference between L21 and this work can be as high as 10 µas within certain ranges of magnitude and colour. This work provides an additional recipe for users of Gaia parallaxes, especially for sources located near the Galactic plane. [ABSTRACT FROM AUTHOR]

Published

2024

11. The impact of UV spectra on searches for extremely metal-poor stars: A study for future CSST observations.

Author

Zhang, Mengmeng, Bu, Yude, Wu, Fan, Shi, Jianrong, Zhang, Jiangchuan, Wu, Huili, Li, Shanshan, Yi, Zhenping, Liu, Meng, and Kong, Xiaoming

Abstract

Extremely metal-poor (EMPs, [Fe/H] < −3.0) and carbon-enhanced EMP (CE-EMP, [Fe/H] < −3.0 and [C/Fe]>  + 1.0) stars are crucial for understanding the chemical evolution and early formation of the galaxies. Current research on EMP stars is limited by small samples, and ultraviolet (UV) band spectra are lacking. The China Space Station Telescope (CSST) will provide high-quality, low-resolution spectra across wavelengths from near-ultraviolet to near-infrared, with a limiting magnitude of about 21 mag. These will help in identifying EMPs and CE-EMP candidates in the distant Milky Way and nearby galaxies. The present study first uses the simulated CSST spectra to quantitatively evaluate the contribution of UV band spectra in predicting [Fe/H], [α/Fe], and [C/Fe]. The results indicate that UV band spectra reduce the mean absolute error by 0.04, 0.04, and 0.03, respectively, with a σ of 0.02, 0.03, and 0.04, respectively. Further spectral analysis reveals that the EMP stars show unique spectral-line features in the UV band, with significant differences compared to stars of higher metallicity, which could help in identifying EMP stars. Additionally, we tested the impact of UV band spectra on identifying EMP and CE-EMP stars at different noise levels and find that models including UV band spectra improve the identification of EMP and CE-EMP stars in terms of accuracy, recall, and F1 score. At low signal-to-noise ratio (S/N), the model including the UV band achieves a recall of 0.94, significantly higher than the model without the UV band (Recall = 0.48), doubling the capability to identify EMP stars. As the S/N increases, the inclusion of the UV band maintains high recall. This suggests that UV spectra in future large surveys could reduce the risk of missing potentially interesting stellar candidates, ensuring a more comprehensive identification of all possible EMP and CE-EMP star candidates. [ABSTRACT FROM AUTHOR]

Published

2024

12. HD 222237 b: a long-period super-Jupiter around a nearby star revealed by radial-velocity and Hipparcos–Gaia astrometry.

Author

Xiao, Guang-Yao, Feng, Fabo, Shectman, Stephen A, Tinney, C G, Teske, Johanna K, Carter, B D, Jones, H R A, Wittenmyer, Robert A, Díaz, Matías R, Crane, Jeffrey D, Wang, Sharon X, Bailey, J, O'Toole, S J, Feinstein, Adina D, Rice, Malena, Essack, Zahra, Montet, Benjamin T, Shporer, Avi, and Butler, R Paul

Subjects

*PLANETARY mass, *PLANETARY orbits, *GAS giants, *PLANETARY systems, *ORBITS (Astronomy)

Abstract

Giant planets on long-period orbits around the nearest stars are among the easiest to directly image. Unfortunately these planets are difficult to fully constrain by indirect methods, e.g. transit and radial velocity (RV). In this study, we present the discovery of a super-Jupiter, HD 222237 b, orbiting a star located |$11.445\pm 0.002$|  pc away. By combining RV data, Hipparcos , and multi-epoch Gaia astrometry, we estimate the planetary mass to be |${5.19}_{-0.58}^{+0.58}\, M_{\rm Jup}$|⁠ , with an eccentricity of |${0.56}_{-0.03}^{+0.03}$| and a period of |${40.8}_{-4.5}^{+5.8}$|  yr, making HD 222237 b a promising target for imaging using the Mid-Infrared Instrument (MIRI) of JWST. A comparative analysis suggests that our method can break the inclination degeneracy and thus differentiate between prograde and retrograde orbits of a companion. We further find that the inferred contrast ratio between the planet and the host star in the F 1550 C filter (⁠|$15.50\, \mu \rm m$|⁠) is approximately |$1.9\times 10^{-4}$|⁠ , which is comparable with the measured limit of the MIRI coronagraphs. The relatively low metallicity of the host star (⁠|$\rm -0.32\, dex$|⁠) combined with the unique orbital architecture of this system presents an excellent opportunity to probe the planet–metallicity correlation and the formation scenarios of giant planets. [ABSTRACT FROM AUTHOR]

Published

2024

13. Orbital architectures of planet-hosting binaries – III. Testing mutual inclinations of stellar and planetary orbits in triple-star systems.

Author

Evans, Elise L, Dupuy, Trent J, Sullivan, Kendall, Kraus, Adam L, Huber, Daniel, Ireland, Michael J, Ansdell, Megan, Kuruwita, Rajika L, Martinez, Raquel A, and Wood, Mackenna L

Subjects

*STELLAR orbits, *PLANETARY orbits, *ASTRONOMICAL transits, *ORBITS (Astronomy), *ORIGIN of planets, *PLANETARY systems, *ASTROMETRY

Abstract

Transiting planets in multiple-star systems, especially high-order multiples, make up a small fraction of the known planet population but provide unique opportunities to study the environments in which planets would have formed. Planet-hosting binaries have been shown to have an abundance of systems in which the stellar orbit aligns with the orbit of the transiting planet, which could give insights into the planet formation process in such systems. We investigate here if this trend of alignment extends to planet-hosting triple-star systems. We present long-term astrometric monitoring of a novel sample of triple-star systems that host Kepler transiting planets. We measured orbit arcs in 21 systems, including 12 newly identified triples, from a homogeneous analysis of our Keck adaptive optics data and, for some systems, Gaia astrometry. We examine the orbital alignment within the nine most compact systems (⁠|$\lesssim 500$|  au), testing if either (or both) of the stellar orbits align with the edge-on orbits of their transiting planets. Our statistical sample of triple systems shows a tendency toward alignment, especially when assessing the alignment probability using stellar orbital inclinations computed from full orbital fits, but is formally consistent with isotropic orbits. Two-population tests where half of the stellar orbits are described by a planet-hosting-binary-like moderately aligned distribution give the best match when the other half (non-planet-hosting) has a Kozai-like misaligned distribution. Overall, our results suggest that our sample of triple-star planet-hosting systems are not fully coplanar systems and have at most one plane of alignment. [ABSTRACT FROM AUTHOR]

Published

2024

14. Astrometry and Photometry of Potentially Dangerous Asteroid 65690 (1991 DG).

Author

Devyatkin, A. V., Gorshanov, D. L., Lvov, V. N., Tsekmeister, S. D., Petrova, S. N., Martyusheva, A. A., and Naumov, K. N.

Subjects

*ASTEROID detection, *ASTEROID orbits, *LIGHT curves, *ASTROMETRY, *ORBITS (Astronomy), *ASTEROIDS

Abstract

In 2020, two telescopes of the State Astrophysical Observatory of the Russian Academy of Sciences, ZA-320M and MTM-500M, obtained series of observations of the potentially dangerous asteroid 65690 (1991 DG) during its approach to the Earth and carried out their astrometric and photometric processing. Using the coordinates of the asteroid and observations from the MRS site, the orbit of the asteroid was clarified, and the circumstances of the approaches to the Earth and Mars were determined, and an assessment was made of the influence of nongravitational effects on its orbit. Based on the results of photometric processing of the asteroid, a light curve was constructed and the period of its axial rotation was determined: P = 4.3193 ± 0.0028 h. [ABSTRACT FROM AUTHOR]

Published

2024

15. The Keck-HGCA Pilot Survey – II. Direct imaging discovery of HD 63754 B, a ∼20 au massive companion near the hydrogen burning limit.

Author

Li, Yiting, Brandt, Timothy D, Franson, Kyle, An, Qier, Tobin, Taylor, Currie, Thayne, Chen, Minghan, Wang, Lanxuan, Dupuy, Trent J, Bowens-Rubin, Rachel, Salama, Maïssa, Lewis, Briley L, Gibbs, Aidan, Bowler, Brendan P, Jensen-Clem, Rebecca, Faherty, Jacqueline, Fitzgerald, Michael P, and Mazin, Benjamin A

Subjects

*ACCELERATION (Mechanics), *LOW mass stars, *BROWN dwarf stars, *INFRARED cameras, *IMAGE processing

Abstract

We present the joint astrometric and direct imaging discovery, mass measurement, and orbital analysis of HD 63754 B (HIP 38216 B), a companion near the stellar-substellar boundary orbiting |$\sim$| 20 au from its Sun-like host. HD 63754 was observed in our ongoing high-contrast imaging survey targeting stars with significant proper-motion accelerations between Hipparcos and Gaia consistent with wide-separation substellar companions. We utilized archival High Resolution Echelle Spectrograph and High Accuracy Radial Velocity Planet Searcher radial velocity (RV) data, together with the host star's astrometric acceleration extracted from the Hipparcos – Gaia Catalog of Accelerations, to predict the location of the candidate companion around HD 63754 A. We subsequently imaged HD 63754 B at its predicted location using the Near Infrared Camera 2 (NIRC2) in the |$L^{\prime }$| band at the W. M. Keck Observatory. We then jointly modelled the orbit of HD 63754 B with RVs, Hipparcos – Gaia accelerations, and our new relative astrometry, measuring a dynamical mass of |${81.9}_{-5.8}^{+6.4} {M_{\rm Jup}}$|⁠ , an eccentricity of |${0.260}_{-0.059}^{+0.065}$|⁠ , and a nearly face-on inclination of |$174.\!\!^\circ 81_{-0.50}^{+0.48}$|⁠. For HD 63754 B, we obtain an |$L^{\prime }$| -band absolute magnitude of |$L^{\prime } = 11.39\pm 0.06$| mag, from which we infer a bolometric luminosity of |$\rm{log(L_{\rm bol}/{\rm{L}_{\odot}})= -4.55 \pm 0.08}$| dex using a comparison sample of L and T dwarfs with measured luminosities. Although uncertainties linger in age and dynamical mass estimates, our analysis points towards HD 63754 B's identity as a brown dwarf on the L/T transition rather than a low-mass star, indicated by its inferred bolometric luminosity and model-estimated effective temperature. Future RV, spectroscopic, and astrometric data such as those from JWST and Gaia Data Release 4 will clarify HD 63754 B's mass, and enable spectral typing and atmospheric characterization. [ABSTRACT FROM AUTHOR]

Published

2024

16. Retrieving stellar parameters and dynamics of AGB stars with Gaia parallax measurements and CO5BOLD RHD simulations.

Author

Béguin, E., Chiavassa, A., Ahmad, A., Freytag, B., and Uttenthaler, S.

Subjects

*CONVECTION (Astrophysics), *STELLAR parallax, *STELLAR oscillations, *STELLAR atmospheres, *ASYMPTOTIC giant branch stars

Abstract

Context. The complex dynamics of asymptotic giant branch (AGB) stars and the resulting stellar winds have a significant impact on the measurements of stellar parameters and amplify their uncertainties. Three-dimensional (3D) radiative hydrodynamic (RHD) simulations of convection suggest that convection-related structures at the surface of AGB star affect the photocentre displacement and the parallax uncertainty measured by Gaia. Aims. We explore the impact of the convection on the photocentre variability and aim to establish analytical laws between the photo-centre displacement and stellar parameters to retrieve such parameters from the parallax uncertainty. Methods. We used a selection of 31 RHD simulations with CO5BOLD and the post-processing radiative transfer code OPTIM3D to compute intensity maps in the Gaia G band [320–1050 nm]. From these maps, we calculated the photocentre position and temporal fluctuations. We then compared the synthetic standard deviation to the parallax uncertainty of a sample of 53 Mira stars observed with Gaia. Results. The simulations show a displacement of the photocentre across the surface ranging from 4 to 13% of the corresponding stellar radius, in agreement with previous studies. We provide an analytical law relating the pulsation period of the simulations and the photocentre displacement as well as the pulsation period and stellar parameters. By combining these laws, we retrieve the surface gravity, the effective temperature, and the radius for the stars in our sample. Conclusions. Our analysis highlights an original procedure to retrieve stellar parameters by using both state-of-the-art 3D numerical simulations of AGB stellar convection and parallax observations of AGB stars. This will help us refine our understanding of these giants. [ABSTRACT FROM AUTHOR]

Published

2024

17. BP3M: Bayesian Positions, Parallaxes, and Proper Motions Derived from the Hubble Space Telescope and Gaia Data.

Author

McKinnon, Kevin A., del Pino, Andrés, Rockosi, Constance M., Apfel, Miranda, Guhathakurta, Puragra, van der Marel, Roeland P., Bennet, Paul, Fardal, Mark A., Libralato, Mattia, Sohn, Sangmo Tony, Vitral, Eduardo, and Watkins, Laura L.

Subjects

*MILKY Way, *PARALLAX, *ELLIPTICAL galaxies, *DWARF galaxies, *SPACE telescopes, *ASTROMETRY

Abstract

We present a hierarchical Bayesian pipeline, BP3M, that measures positions, parallaxes, and proper motions (PMs) for cross-matched sources between Hubble Space Telescope (HST) images and Gaia—even for sparse fields (N * < 10 per image)—expanding from the recent GaiaHub tool. This technique uses Gaia-measured astrometry as priors to predict the locations of sources in HST images, and is therefore able to put the HST images onto a global reference frame without the use of background galaxies/QSOs. Testing our publicly available code in the Fornax and Draco dwarf spheroidal galaxies, we measure PMs that are a median of 8–13 times more precise than Gaia DR3 alone for 20.5 < G < 21 mag. We are able to explore the effect of observation strategies on BP3M astrometry using synthetic data, finding an optimal strategy to improve parallax and position precision at no cost to the PM uncertainty. Using 1619 HST images in the sparse COSMOS field (median nine Gaia sources per HST image), we measure BP3M PMs for 2640 unique sources in the 16 < G < 21.5 mag range, 25% of which have no Gaia PMs; the median BP3M PM uncertainty for 20.25 < G < 20.75 mag sources is 0.44 mas yr−1 compared to 1.03 mas yr−1 from Gaia, while the median BP3M PM uncertainty for sources without Gaia-measured PMs (20.75 < G < 21.5 mag) is 1.16 mas yr−1. The statistics that underpin the BP3M pipeline are a generalized way of combining position measurements from different images, epochs, and telescopes, which allows information to be shared between surveys and archives to achieve higher astrometric precision than that from each catalog alone. [ABSTRACT FROM AUTHOR]

Published

2024

18. Influence of selection criteria on the interpretation of rotational behaviour of wide-binary star systems.

Author

Cookson, S A

Subjects

*MECHANICS (Physics), *STELLAR dynamics, *BINARY stars, *GENERAL relativity (Physics), *STANDARD deviations

Abstract

Binary star systems are expected to follow Newtonian dynamics similarly to planetary systems. However, reports have been made of wide binary systems with separations around 0.01 pc and larger, showing potential deviations from standard Newtonian motion. This phenomenon, suggestive of the flattening of galactic rotation curves, calls for closer inspection. This study presents an analysis of wide binary stars using data from Gaia Data Release 3 (DR3), a space-based astrometry mission funded by the European Space Agency. The study compares different choices of selection criteria to examine the nature of these apparent anomalous kinematics within the solar neighbourhood. The Gaia data set furnishes detailed parameters, including radial velocity, mass, age, and binary probability in addition to standard parameters. A custom Python tool named bynary facilitated both data processing and analysis. This report reveals that the signs of any anomalous signals systematically diminish as the initial selection criteria are relaxed for degrouping while subsequent filtering remains stringent, leading to the complete elimination of any apparent non-Newtonian motion for binary separations within 0.5 pc. The study shows that any observed anomalous behaviour in solar neighbourhood wide binaries within 130 pc must be produced either by faint companion stars orbiting primary or secondary stars, or by flyby stars. The findings emphasize the importance of the choice of selection criteria in disentangling genuine binary dynamics from external influences. The conclusions align with the predictions of Newtonian mechanics and general relativity, though they do not exclude other phenomena at larger scales. [ABSTRACT FROM AUTHOR]

Published

2024

19. Asteroids discovered in the Baldone Observatory between 2017 and 2022: The orbits of asteroid 428694 Saule and 330836 Orius

Author

Wlodarczyk Ireneusz, Černis Kazimieras, and Eglitis Ilgmar

Subjects

minor planets, asteroids, search, astrometry, orbits, Astronomy, QB1-991

Abstract

We discovered 83 asteroids at the Baldone Astrophysical Observatory (MPC code 069) in 2017–2022. We studied one of the dynamically interesting Apollo (Near Earth object) observed at the Baldone Astronomical Observatory, namely 428694 Saule (2008 OS9) and the Centaur-type asteroid 330836 Orius (2009 HW77). We studied the evolution of the asteroid Saule’s rotation period, obliquity, and spin axis together with its non-gravitational parameter da∕dt{\rm{d}}a/{\rm{d}}t connected with the Yarkovsky effect. Additionally, we studied the orbit of the Amor-type asteroid 2017 UW42, which has the significant non-gravitational parameter A2A2.

Published

2024

20. A deep analysis for New Horizons' KBO search images.

Author

Yoshida, Fumi, Yanagisawa, Toshifumi, Ito, Takashi, Kurosaki, Hirohisa, Yoshikawa, Makoto, Kamiya, Kohki, Jiang, Ji-an, Stern, Alan, Fraser, Wesley C, Benecchi, Susan D, and Verbiscer, Anne J

Subjects

*FIELD programmable gate arrays, *KUIPER belt, *NEAR-earth asteroids, *IMAGE processing, *ASTROMETRY, *ASTEROIDS

Abstract

Observation datasets acquired by the Hyper Suprime-Cam (HSC) on the Subaru Telescope for NASA's New Horizons mission target search were analyzed through a method devised by JAXA. The method makes use of Field Programmable Gate arrays and was originally used to detect fast-moving objects such as space debris or near-Earth asteroids. Here we present an application of the method to detect slow-moving Kuiper Belt Objects (KBOs) in the New Horizons target search observations. A cadence that takes continuous images of one HSC field of view for half a night fits the method well. The observations for the New Horizons Kuiper Belt Extended Mission (NH/KEM) using HSC began in 2020 May, and are ongoing. Here we show our result of the analysis of the dataset acquired from 2020 May through 2021 June that have already passed the proprietary period and are open to the public. We detected 84 KBO candidates in the 2020 June and 2021 June datasets, when the observation field was close to opposition. [ABSTRACT FROM AUTHOR]

Published

2024

21. A path towards constraining the evolution of the interstellar medium and outflows in the Milky Way using APOGEE.

Author

Sharda, Piyush, Ting, Yuan-Sen, and Frankel, Neige

Subjects

*INTERSTELLAR medium, *MILKY Way, *DISTRIBUTION of stars, *STAR formation, *GALACTIC evolution, *AGE of stars, *ASTROMETRY

Abstract

In recent years, the study of the Milky Way has significantly advanced due to extensive spectroscopic surveys of its stars, complemented by astroseismic and astrometric data. However, it remains disjoint from recent advancements in understanding the physics of the Galactic interstellar medium (ISM). This paper introduces a new model for the chemical evolution of the Milky Way that can be constrained on stellar data, because it combines a state-of-the-art ISM model with a Milky Way stellar disc model. Utilizing a data set of red clump stars from APOGEE, known for their precise ages and metallicities, we concentrate on the last 6 billion years – a period marked by Milky Way's secular evolution. We examine the oxygen abundance in the low- |$\alpha$| disc stars relative to their ages and birth radii, validating or constraining critical ISM parameters that remain largely unexplored in extragalactic observations. The models that successfully reproduce the radius–metallicity distribution and the age–metallicity distribution of stars without violating existing ISM observations indicate a need for modest differential oxygen enrichment in Galactic outflows, meaning that the oxygen abundance of outflows is higher than the local ISM abundance, irrespective of outflow mass loading. The models also suggest somewhat elevated ISM gas velocity dispersion levels over the past 6 billion years compared to galaxies of similar mass. The extra turbulence necessary could result from energy from gas accretion onto the Galaxy, supernovae clustering in the ISM, or increased star formation efficiency per freefall time. This work provides a novel approach to constraining the Galactic ISM and outflows, leveraging the detailed insights available from contemporary Milky Way surveys. [ABSTRACT FROM AUTHOR]

Published

2024

22. Single-epoch and Differential Astrometric Microlensing of Quasars.

Author

Forés-Toribio, R., Mediavilla, E., Muñoz, J. A., Jiménez-Vicente, J., Fian, C., and del Burgo, C.

Subjects

*QUASARS, *MICROLENSING (Astrophysics), *ASTROMETRY, *ACCRETION disks, *DARK matter, *CENTROID

Abstract

We propose and discuss a new experimental approach to measure the centroid shift induced by gravitational microlensing in the images of lensed quasars (astrometric microlensing). Our strategy is based on taking the photocenter of a region in the quasar large enough as to be insensitive to microlensing as reference to measure the centroid displacement of the continuum. In this way, single-epoch measurements of astrometric microlensing can be performed. Using numerical simulations, we show that, indeed, the centroid shift monotonically decreases as the size of the emitting region increases, and only for relatively large regions, like the broad line region (BLR), does the centroid shift become negligible. This opens interesting possibilities to study the stratification of the different emitters in the accretion disk and the BLR. We estimate the amplitude of the centroid shifts for 79 gravitationally lensed images and study more thoroughly the special cases Q2237+030 A, RXJ1131-1231 A, PG1115+080 A2, and SDSS J1004+4112 A. We propose to use spectro-astrometry to simultaneously obtain the photocenters of the continuum and of different emission line regions since, with the precision of forthcoming instruments, astrometric microlensing by ∼1 M ⊙ mass microlenses may be detected in many quasar lensed images. When we consider more massive micro/millilenses, M ≳ 10 M ⊙, often proposed as the constituents of dark matter, the BLR becomes sensitive to microlensing and can no longer be used as a positional reference to measure centroid shifts. Differential microlensing between the images of a lensed quasar along several epochs should be used instead. [ABSTRACT FROM AUTHOR]

Published

2024

23. High-precision astrometry with VVV: II. A near-infrared extension of Gaia into the Galactic plane.

Author

Griggio, M., Libralato, M., Bellini, A., Bedin, L. R., Anderson, J., Smith, L. C., and Minniti, D.

Subjects

*GALACTIC bulges, *GALACTIC center, *SPACE telescopes, *DATA release, *PARALLAX, *ASTROMETRY

Abstract

Aims. We use near-infrared, ground-based data from the VISTA Variables in the Via Lactea (VVV) survey to indirectly extend the astrometry provided by the Gaia catalog to objects in heavily extinct regions toward the Galactic bulge and plane that are beyond Gaia's reach. Methods. We made use of state-of-the-art techniques developed for high-precision astrometry and photometry with the Hubble Space Telescope to process the VVV data. We employed empirical, spatially variable, effective point spread functions and local transformations to mitigate the effects of systematic errors, like residual geometric distortion and image motion, and to improve measurements in crowded fields and for faint stars. We also anchored our astrometry to the absolute reference frame of Gaia Data Release 3. Results. We measure between 20 and 60 times more sources than Gaia in the region surrounding the Galactic center, obtaining a single-exposure precision of about 12 mas and a proper-motion precision of better than 1 mas yr−1 for bright, unsaturated sources. Our astrometry provides an extension of Gaia into the Galactic center. We publicly release the astro-photometric catalogs of the two VVV fields considered in this work, which contain a total of ~3.5 million sources. Our catalogs cover ~3 sq. deg, about 0.5% of the entire VVV survey area. [ABSTRACT FROM AUTHOR]

Published

2024

24. The spin, expansion, and contraction of open star clusters.

Author

Jadhav, Vikrant V., Kroupa, Pavel, Wu, Wenjie, Pflamm-Altenburg, Jan, and Thies, Ingo

Subjects

*ANGULAR momentum (Mechanics), *N-body simulations (Astronomy), *GALACTIC dynamics, *ASTROMETRY, *CLUSTER analysis (Statistics)

Abstract

Context. Empirical constraints on the internal dynamics of open clusters are important for understanding their evolution and evaporation. High-precision astrometry from Gaia DR3 is thus useful to observe aspects of the cluster dynamics. Aims. This work aims to identify dynamically peculiar clusters such as spinning and expanding clusters. We also quantify the spin frequency and expansion rate and compare them with N-body models to identify the origins of the peculiarities. Methods. We used the latest Gaia DR3 and archival spectroscopic surveys to analyse the radial velocities and proper motions of the cluster members in 1379 open clusters. A systematic analysis of synthetic clusters was performed to demonstrate the observability of the cluster spin along with effects of observational uncertainties. N-body simulations were used to understand the evolution of cluster spin and expansion for initially non-rotating clusters. Results. We identified spin signatures in ten clusters (and 16 candidates). Additionally, we detected expansion in 18 clusters and contraction in three clusters. The expansion rate is compatible with previous theoretical estimates based on the expulsion of residual gas. The orientation of the spin axis is independent of the orbital angular momentum. Conclusions. The spin frequencies are much larger than what was expected from simulated, initially non-rotating clusters. This indicates that > 1% of the clusters are born rotating and/or they have undergone strong interactions. Higher precision observations are required to increase the sample of such dynamically peculiar clusters and to characterise them. [ABSTRACT FROM AUTHOR]

Published

2024

25. Physical parameters and orbital evolution of asteroids in retrograde orbits.

Author

Wlodarczyk, I.

Subjects

*ASTEROID orbits, *CELESTIAL mechanics, *ASTEROID detection, *ASTROMETRY, *ROTATIONAL motion, *ASTEROIDS

Abstract

Context. We studied the dynamical orbital and physical evolution of all 21 numbered and 13 selected unnumbered asteroids in retrograde orbits. Aims. Based on all published observations of studied asteroids in retrograde orbits, we computed their starting orbital elements, absolute magnitudes, and diameters, together with the non-gravitational parameters A2 and da/dt. Methods. Using publicly available orbital computation methods, we studied the dynamical evolution of orbital elements and the physical parameters of asteroids: rotation period, spin direction, and the non-gravitational parameters A2. Results. Lyapunov times (LT) for studied asteroids are short, from 60 to 36 496 yr, with a mean of 5978. Without considering non-gravitational effects, LT is longer: values range from 328 to 63 165 yr, with a mean of 6392. Over the next 10 Myr and beyond, the rotation period of the studied asteroids P decreases by approximately 8%. Moreover, 15% of the clones slow down. Conclusions. The starting spin distribution becomes flatter, with only one large maximum in the range (0–5) deg containing 279 clones (i.e. approximately 13%). However, the non-gravitational parameter da/dt has a maximum value of around (0–0.04)× 10−5 au day−2. [ABSTRACT FROM AUTHOR]

Published

2024

26. The longevity of the oldest open clusters: Structural parameters of NGC 188, NGC 2420, NGC 2425, NGC 2682, NGC 6791, and NGC 6819.

Author

Alvarez-Baena, N., Carrera, R., Thompson, H., Balaguer-Nuñez, L., Bragaglia, A., Jordi, C., Silva-Villa, E., and Vallenari, A.

Subjects

*OPEN clusters of stars, *STELLAR evolution, *DISTRIBUTION of stars, *ORBITS (Astronomy), *ASTROMETRY, *GLOBULAR clusters

Abstract

Context. The dynamical evolution of open clusters is driven by stellar evolution, internal dynamics, and external forces, which according to dynamical simulations will lead to their evaporation over a timescale of about 1 Ga. However, about 10% of the known open clusters are older. These latter are special systems whose detailed properties are related to their dynamical evolution and the balance between mechanisms of cluster formation and dissolution. Aims. We investigated the spatial distribution and structural parameters of six open clusters older than 1 Ga in order to constrain their dynamical evolution and longevity. Methods. We identified members using Gaia EDR3 data up to a distance of 150 pc from the centre of each cluster. We investigated the spatial distribution of stars inside each cluster to understand their degree of mass segregation. Finally, in order to interpret the obtained radial density profiles, we reproduced them using the lowered isothermal model explorer with PYthon (LIMEPY) and the spherical potential escapers stitched (SPES) models. Results. All the studied clusters appear to be more extended than previously reported in the literature. The spatial distributions of three of them show some structures aligned with their orbits. These structures may be related to the existence of extra tidal stars. Moreover, we find that about 20% of their members have sufficient energy to leave the systems or are already unbound. Together with their initial masses, their distances to the Galactic plane may play significant roles in their survival. We find clear evidence that the most dynamically evolved clusters do not fill their Roche volumes, appearing more concentrated than the others. Finally, we find a cusp–core dichotomy in the central regions of the studied clusters, which shows some similarities to that observed among globular clusters. [ABSTRACT FROM AUTHOR]

Published

2024

27. Searching for OB-type pre-supernova binary companions inside supernova remnants.

Author

Dinçel, B, Uzuner, M, Neuhäuser, R, Pannicke, A, Yerli, S K, Ankay, A, Mugrauer, M, and Torres, G

Subjects

*SUPERNOVA remnants, *STELLAR parallax, *MAIN sequence (Astronomy), *SUPERGIANT stars, *STARS, *ASTROMETRY

Abstract

We searched for OB-runaway stars inside supernova remnants (SNRs) as a pre-supernova binary companion. As the majority of massive stars are found in close binary systems, a runaway star ejected by the orbital energy after the supernova (SN) is expected to be found. Considering a binary mass fraction, q = 0.25−1.0, the runaway star is likely to have an OB spectral type. We selected 12 SNRs at Galactic longitudes 109°−189°. Using Gaia astrometry, we selected stars having consistent distances with those of the SNRs and showing a peculiar proper motion directed away from the central region of the SNRs. We also determined the radial distribution of the extinction towards the SNRs and estimated the spectral types of the OB-runaway candidates through Gaia and Two Micron All Sky Survey photometry. We found two candidates among 12 SNRs. By spectroscopic observations, Gaia DR3 195632152560621440 inside SNR G166.0 + 4.3 was found to be an evolved A3 type star that cannot be the pre-SN binary companion to the progenitor. Gaia DR3 513927750767375872 inside SNR HB 3 is the only OB-runaway candidate (2D space velocity of 33.3 ± 3.3 km s−1). Based on photometric study, the star can be an early B-type main-sequence star with a slightly higher extinction relative to the SNR; however, it might instead be an evolved A-type star at the same distance. The other 11 SNRs do not host an OB-runaway star within their central regions. Although the runaway search was performed in a large interval of distance and extinction, we also estimated distances to the SNRs. [ABSTRACT FROM AUTHOR]

Published

2024

28. Toward HPC application portability via C++ PSTL: the Gaia AVU-GSR code assessment.

Author

Malenza, Giulio, Cesare, Valentina, Aldinucci, Marco, Becciani, Ugo, and Vecchiato, Alberto

Subjects

*C++, *PROCESS capability, *HIGH performance computing, *MILKY Way, *LINEAR equations, *LINEAR systems

Abstract

The computing capacity needed to process the data generated in modern scientific experiments is approaching ExaFLOPs. Currently, achieving such performances is only feasible through GPU-accelerated supercomputers. Different languages were developed to program GPUs at different levels of abstraction. Typically, the more abstract the languages, the more portable they are across different GPUs. However, the less abstract and co-designed with the hardware, the more room for code optimization and, eventually, the more performance. In the HPC context, portability and performance are a fairly traditional dichotomy. The current C++ Parallel Standard Template Library (PSTL) has the potential to go beyond this dichotomy. In this work, we analyze the main performance benefits and limitations of PSTL using as a use-case the Gaia Astrometric Verification Unit-Global Sphere Reconstruction parallel solver developed by the European Space Agency Gaia mission. The code aims to find the astrometric parameters of ∼ 10 8 stars in the Milky Way by iteratively solving a linear system of equations with the LSQR algorithm, originally GPU-ported with the CUDA language. We show that the performance obtained with the PSTL version, which is intrinsically more portable than CUDA, is comparable to the CUDA one on NVIDIA GPU architecture. [ABSTRACT FROM AUTHOR]

Published

2024

29. Orbit determination of asteroid (469219) Kamo'oalewa using a combination of historical and new observations.

Author

Huang, Hao, Liu, Shanhong, Ge, Liang, Cao, Jianfeng, Li, Xie, and Gao, Jian

Subjects

*ORBIT determination, *ASTEROIDS, *ASTEROID orbits, *NEAR-earth asteroids, *ASTRONOMICAL observatories, *ORBITS (Astronomy)

Abstract

The orbit solution of near-Earth asteroids heavily relies on ground-based optical observations. The orbit uncertainty is limited by the insufficient observation quantity and quality. The Chinese Tianwen-2 mission targets a near-Earth asteroid (469219) Kamo'oalewa and a main-belt comet, 311P/PANSTARRS. To accurately determine the orbit of Kamo'oalewa, more optical observations are needed. Autonomous observation experiments focusing on Kamo'oalewa were carried out using the 2.16-m telescope at the Xinglong Observatory of the National Astronomical Observatory of China. We found that this telescope could observe near-Earth asteroids as faint as a magnitude of 22.8. Based on the stacking method and trailed star extraction algorithm, 14 optical observations were obtained from 2022 to 2024. The orbit for Kamo'oalewa was determined by combining our observations with historical observations between 2004 and 2024. The inclusion of our observations results in improved orbital uncertainties of Kamo'oalewa by 18.67, 7.93, and 11.12 km (1σ) in the X, Y , and Z directions, respectively. Furthermore, by combining all existing and simulated observations, the uncertainty of the orbital determination of Kamo'oalewa was analysed. When using an additional 180 group observations from 3 Chinese observatories over 2 yr, the orbital uncertainties of Kamo'oalewa in the 3 directions could be reduced to 30 km (1σ). [ABSTRACT FROM AUTHOR]

Published

2024

30. JWST imaging of the closest globular clusters—I. Possible infrared excess among white dwarfs in NGC 6397.

Author

Bedin, L. R., Nardiello, D., Salaris, M., Libralato, M., Bergeron, P., Burgasser, A. J., Apai, D., Griggio, M., Scalco, M., Anderson, J., Gerasimov, R., and Bellini, A.

Subjects

*SPACE telescopes, *GLOBULAR clusters, *PLANETARY systems, *ASTROMETRY, *PHOTOMETRY

Abstract

We present James Webb Space Telescope observations of the globular cluster NGC 6397 and use them to extend to infrared wavelengths the characterization of the cluster's entire white dwarf (WD) cooling sequence (CS). The data allows us to probe fundamental astrophysical WD properties and to search for evidence in their colors for (or against) the existence of ancient planetary systems. The existing archival Hubble Space Telescope imaging data obtained ∼18$$ \sim 18 $$ years ago reach ultra‐deep optical magnitudes (V∼31$$ V\sim 31 $$) and allow us to derive a near‐perfect separation between field and cluster members. We detect an apparent split in the lower part of the WD CS of NGC 6397. The red part of the WD CS, containing about 25% of the total, exhibits significant IR‐excess of up to ΔmF322W2∼0.5$$ \Delta {m}_{\mathrm{F}322\mathrm{W}2}\sim 0.5 $$ mag. These infrared excesses require both theoretical and observational follow‐ups to confirm their veracity and to ascertain their true nature. [ABSTRACT FROM AUTHOR]

Published

2024

31. Astrometry as a Tool for Discovering and Weighing Faint Companions to Nearby Stars.

Author

Brandt, Timothy D.

Subjects

*STELLAR mass, *BROWN dwarf stars, *ASTROMETRY, *DWARF planets, *ORBITS (Astronomy), *SYNCOPE

Abstract

This tutorial covers the use of absolute astrometry, in particular from the combination of the Hipparcos and Gaia missions, to identify faint companions to nearby stars and to measure the masses and orbits of those companions. Absolute astrometry has been used with increasing success to discover new planets and brown dwarfs and to measure masses and orbits for systems with periods as long as centuries. This tutorial summarizes the nature of the underlying astrometric data, the approach typically used to fit orbits, and the assumptions about that data implicit throughout the process. It attempts to provide intuition for the sensitivity of astrometry as a function of stellar and companion properties and how the available constraints depend on the character and quantity of data available. This tutorial is written for someone with some background in astronomy but with no more than a minimal acquaintance with astrometry or orbit fitting. [ABSTRACT FROM AUTHOR]

Published

2024

32. Not So Fast: A New Catalog of Meteor Persistent Trains.

Author

Cordonnier, L. E., Obenberger, K. S., Holmes, J. M., Taylor, G. B., and Vida, D.

Subjects

METEORS, METEOR showers, INSPECTION & review, METEOROIDS, DATABASES, CATALOGS

Abstract

This paper presents the results of a nearly 2‐year long campaign to detect and analyze meteor persistent trains (PTs)—self‐emitting phenomena which can linger up to an hour after their parent meteor. The modern understanding of PTs has been primarily developed from the Leonid storms at the turn of the century; our goal was to assess the validity of these conclusions using a diverse sample of meteors with a wide range of velocities and magnitudes. To this end, year‐round observations were recorded by the Widefield Persistent Train camera, 2nd edition (WiPT2) and were passed through a pipeline to filter out airplanes and flag potential meteors. These were classified by visual inspection based on the presence and duration of trains. Observed meteors were cross‐referenced with the Global Meteor Network (GMN) database, which independently detects and calculates meteor parameters, enabling statistical analysis of PT‐leaving meteors. There were 4,726 meteors codetected by the GMN, with 636 of these leaving trains. Among these were a large population of slow, dim meteors that left PTs; these slower meteors had a greater train production rate relative to their faster counterparts. Unlike prior research, we did not find a clear magnitude cutoff or a strong association with fast meteor showers. Additionally, we note several interesting trends not previously reported, which include PT eligibility being primarily determined by a meteor's terminal height and an apparent dynamical origin dependence that likely reflects physical meteoroid properties. Key Points: New observations of meteor persistent trains (PTs) are not consistent with many of the previous assumptionsMost PTs were left by relatively slow and dim meteors which are traditionally not expected to produce themWe found that meteor properties such as terminal altitude and dynamical origin affect the likelihood that PTs develop [ABSTRACT FROM AUTHOR]

Published

2024

33. Observing the galactic underworld: predicting photometry and astrometry from compact remnant microlensing events.

Author

Sweeney, David, Tuthill, Peter, Krone-Martins, Alberto, Mérand, Antoine, Scalzo, Richard, and Martinod, Marc-Antoine

Subjects

*BLACK holes, *NEUTRON stars, *PHOTOMETRY, *ELECTROMAGNETIC spectrum, *ASTROMETRY, *FORECASTING

Abstract

Isolated black holes (BHs) and neutron stars (NSs) are largely undetectable across the electromagnetic spectrum. For this reason, our only real prospect of observing these isolated compact remnants is via microlensing; a feat recently performed for the first time. However, characterization of the microlensing events caused by BHs and NSs is still in its infancy. In this work, we perform N -body simulations to explore the frequency and physical characteristics of microlensing events across the entire sky. Our simulations find that every year we can expect |$88_{-6}^{+6}$| BH, |$6.8_{-1.6}^{+1.7}$| NS, and |$20^{+30}_{-20}$| stellar microlensing events which cause an astrometric shift larger than 2 mas. Similarly, we can expect |$21_{-3}^{+3}$| BH, |$18_{-3}^{+3}$| NS, and |$7500_{-500}^{+500}$| stellar microlensing events which cause a bump magnitude larger than 1 mag. Leveraging a more comprehensive dynamical model than prior work, we predict the fraction of microlensing events caused by BHs as a function of Einstein time to be smaller than previously thought. Comparison of our microlensing simulations to events in Gaia finds good agreement. Finally, we predict that in the combination of Gaia and Gaia NIR data there will be |$14700_{-900}^{+600}$| BH and |$1600_{-200}^{+300}$| NS events creating a centroid shift larger than 1 mas and |$330_{-120}^{+100}$| BH and |$310_{-100}^{+110}$| NS events causing bump magnitudes >1. Of these, <10 BH and |$5_{-5}^{+10}$| NS events should be detectable using current analysis techniques. These results inform future astrometric mission design, such as Gaia NIR, as they indicate that, compared to stellar events, there are fewer observable BH events than previously thought. [ABSTRACT FROM AUTHOR]

Published

2024

34. An evaluation of the BALROG and RoboBA algorithms for determining the position of Fermi/GBM GRBs.

Author

López, K Ocelotl C, Watson, Alan M, Lee, William H, Becerra, R L, and Pereyra, Margarita

Subjects

*GAMMA ray bursts, *GRAVITATIONAL waves, *ALGORITHMS, *PROTHROMBIN

Abstract

The Fermi /GBM instrument is a vital source of detections of gamma-ray bursts and has an increasingly important role to play in understanding gravitational-wave transients. In both cases, its impact is increased by accurate positions with reliable uncertainties. We evaluate the RoboBA and BALROG algorithms for determining the position of gamma-ray bursts detected by the Fermi /GBM instrument. We construct a sample of 54 bursts with detections both by Swift /BAT and by Fermi /GBM. We then compare the positions predicted by RoboBA and BALROG with the positions measured by BAT, which we can assume to be the true position. We find that RoboBA and BALROG are similarly precise for bright bursts whose uncertainties are dominated by systematic errors, but RoboBA performs better for faint bursts whose uncertainties are dominated by statistical noise. We further find that the uncertainties in the positions predicted by RoboBA are consistent with the distribution of position errors, whereas BALROG seems to be underestimating the uncertainties by a factor of about 2. Additionally, we consider the implications of these results for the follow-up of the optical afterglows of Fermi /GBM bursts. In particular, for the DDOTI wide-field imager we conclude that a single pointing is best. Our sample would allow a similar study to be carried out for other telescopes. [ABSTRACT FROM AUTHOR]

Published

2024

35. Astrometric weak lensing with Gaia DR3 and future catalogues: searches for dark matter substructure.

Author

Mondino, Cristina, Tsantilas, Andreas, Taki, Anna-Maria, Van Tilburg, Ken, and Weiner, Neal

Subjects

*DARK matter, *MAGELLANIC clouds, *STELLAR mass, *MILKY Way, *MICROPHYSICS, *ASTROMETRY

Abstract

Small-scale dark matter structures lighter than a billion solar masses are an important probe of primordial density fluctuations and dark matter microphysics. Due to their lack of starlight emission, their only guaranteed signatures are gravitational in nature. We report on results of a search for astrometric weak lensing by compact dark matter subhaloes in the Milky Way with Gaia DR3 data. Using a matched-filter analysis to look for correlated imprints of time-domain lensing on the proper motions of background stars in the Magellanic Clouds, we exclude order-unity substructure fractions in haloes with masses Ml between 107 and |$10^9 \, {\rm M}_\odot$| and sizes of one parsec or smaller. We forecast that a similar approach based on proper accelerations across the entire sky with data from Gaia DR4 may be sensitive to substructure fractions of fl ≳ 10−3 in the much lower mass range of |$10 \, {\rm M}_\odot \lesssim M_l \lesssim 3 \times 10^3 \, {\rm M}_\odot$|⁠. We further propose an analogous technique for stacked star–star lensing events in the regime of large impact parameters. Our first implementation is not yet sufficiently sensitive but serves as a useful diagnostic and calibration tool; future data releases should enable average stellar mass measurements using this stacking method. 1 [ABSTRACT FROM AUTHOR]

Published

2024

36. Proper motion of the radio jets in two blazars at redshift above 3.

Author

Krezinger, Máté, Frey, Sándor, Perger, Krisztina, Gabányi, Krisztina É, An, Tao, Zhang, Yingkang, Gurvits, Leonid I, Titov, Oleg, Melnikov, Alexey, and Paragi, Zsolt

Subjects

*VERY long baseline interferometry, *ASTROMETRY, *ACTIVE galactic nuclei, *REDSHIFT, *RADIO galaxies, *ACTIVE galaxies

Abstract

There is still a limited number of high-redshift (z > 3) active galactic nuclei (AGNs) whose jet kinematics have been studied with very long baseline interferometry (VLBI). Without a dedicated proper motion survey, regularly conducted astrometric VLBI observations of bright radio-emitting AGN with sensitive arrays can be utilized to follow changes in the jets, by means of high-resolution imaging and brightness distribution modelling. Here, we present a first-time VLBI jet kinematic study of NVSS J080518 + 614423 (z = 3.033) and NVSS J165844 − 073918 (z = 3.742), two flat-spectrum radio quasars that display milliarcsecond-scale jet morphology. Archival astrometric observations carried out mainly with the Very Long Baseline Array, supplemented by recent data taken with the European VLBI Network, allowed us to monitor changes in their radio structure in the 7.6−8.6 GHz frequency band, covering almost two decades. By identifying individual jet components at each epoch, we were able to determine the apparent proper motion for multiple features in both sources. Apparent superluminal motions range |$(1-14)\, c$|⁠ , and are found to be consistent with studies of other high-redshift AGN targets. Using the physical parameters derived from the brightness distribution modelling, we estimate the Doppler-boosting factors (δ ≈ 11.2 and δ ≈ 2.7), the Lorentz factors (Γ ≈ 7.4 and Γ ≈ 36.6), and the jet viewing angles (θ ≈ 4.4° and θ ≈ 8.0°), for NVSS J080518 + 614423 and NVSS J165844 − 073918, respectively. The data revealed a stationary jet component with negligible apparent proper motion in NVSS J165844 − 073918. [ABSTRACT FROM AUTHOR]

Published

2024

37. JASMINE: Near-infrared astrometry and time-series photometry science.

Author

Kawata, Daisuke, Kawahara, Hajime, Gouda, Naoteru, Secrest, Nathan J, Kano, Ryouhei, Kataza, Hirokazu, Isobe, Naoki, Ohsawa, Ryou, Usui, Fumihiko, Yamada, Yoshiyuki, Graham, Alister W, Pettitt, Alex R, Asada, Hideki, Baba, Junichi, Bekki, Kenji, Dorland, Bryan N, Fujii, Michiko, Fukui, Akihiko, Hattori, Kohei, and Hirano, Teruyuki

Subjects

*GALACTIC center, *JASMINE, *PHOTOMETRY, *ASTROMETRY, *VARIABLE stars, *MILKY Way

Abstract

The Japan Astrometry Satellite Mission for INfrared Exploration (JASMINE) is a planned M-class science space mission by the Institute of Space and Astronautical Science, the Japan Aerospace Exploration Agency. JASMINE has two main science goals. One is Galactic archaeology with a Galactic Center survey, which aims to reveal the Milky Way's central core structure and formation history from Gaia-level (∼25 |${\mu} $| as) astrometry in the near-infrared (NIR) H w band (1.0–1.6  |${\mu} $| m). The other is an exoplanet survey, which aims to discover transiting Earth-like exoplanets in the habitable zone from NIR time-series photometry of M dwarfs when the Galactic Center is not accessible. We introduce the mission, review many science objectives, and present the instrument concept. JASMINE will be the first dedicated NIR astrometry space mission and provide precise astrometric information on the stars in the Galactic Center, taking advantage of the significantly lower extinction in the NIR. The precise astrometry is obtained by taking many short-exposure images. Hence, the JASMINE Galactic Center survey data will be valuable for studies of exoplanet transits, asteroseismology, variable stars, and microlensing studies, including discovery of (intermediate-mass) black holes. We highlight a swath of such potential science, and also describe synergies with other missions. [ABSTRACT FROM AUTHOR]

Published

2024

38. Revised orbits of the two nearest Jupiters

Author

Feng, Fabo, Butler, R Paul, Vogt, Steven S, Holden, Bradford, and Rui, Yicheng

Subjects

methods: data analysis, techniques: radial velocities, astrometry, exoplanets, stars: individual: e Eridani, stars: individual: e Ind A, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

ABSTRACT: With its near-to-mid-infrared high-contrast imaging capabilities, JWST is ushering us into a golden age of directly imaging Jupiter-like planets. As the two closest cold Jupiters, ε Ind A b and ε Eridani b have sufficiently wide orbits and adequate infrared emissions to be detected by JWST. To detect more Jupiter-like planets for direct imaging, we develop a gost-based method to analyse radial velocity data and multiple Gaia data releases simultaneously. Without approximating instantaneous astrometry by catalogue astrometry, this approach enables the use of multiple Gaia data releases for detection of both short-period and long-period planets. We determine a mass of $2.96_{-0.38}^{+0.41}$ MJup and a period of $42.92_{-4.09}^{+6.38}$ yr for ε Ind A b. We also find a mass of $0.76_{-0.11}^{+0.14}$ MJup , a period of $7.36_{-0.05}^{+0.04}$ yr, and an eccentricity of 0.26$_{-0.04}^{+0.04}$ MJup, for ε Eridani b. The eccentricity differs from that given by some previous solutions, probably due to the sensitivity of orbital eccentricity to noise modelling. Our work refines the constraints on orbits and masses of the two nearest Jupiters and demonstrate the feasibility of using multiple Gaia data releases to constrain Jupiter-like planets.

Published

2023

39. Direct Solver Aiming at Elimination of Systematic Errors in 3D Stellar Positions

Author

Ryabinin, Konstantin, Sarras, Gerasimos, Löffler, Wolfgang, Biermann, Michael, Hartmanis, Juris, Founding Editor, van Leeuwen, Jan, Series Editor, Hutchison, David, Editorial Board Member, Kanade, Takeo, Editorial Board Member, Kittler, Josef, Editorial Board Member, Kleinberg, Jon M., Editorial Board Member, Kobsa, Alfred, Series Editor, Mattern, Friedemann, Editorial Board Member, Mitchell, John C., Editorial Board Member, Naor, Moni, Editorial Board Member, Nierstrasz, Oscar, Series Editor, Pandu Rangan, C., Editorial Board Member, Sudan, Madhu, Series Editor, Terzopoulos, Demetri, Editorial Board Member, Tygar, Doug, Editorial Board Member, Weikum, Gerhard, Series Editor, Vardi, Moshe Y, Series Editor, Goos, Gerhard, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Franco, Leonardo, editor, de Mulatier, Clélia, editor, Paszynski, Maciej, editor, Krzhizhanovskaya, Valeria V., editor, Dongarra, Jack J., editor, and Sloot, Peter M. A., editor

Published

2024

40. Origin and Evolution of Enceladuss Tidal Dissipation.

Author

Neveu, Marc, Howett, Carly, and Nimmo, Francis

Subjects

Astrometry, Impact flux, Orbital evolution, Resonance locking, Satellites of Saturn, Tidal heating

Abstract

Enceladus possesses a subsurface ocean beneath a conductive ice shell. Based on shell thickness models, the estimated total conductive heat loss from Enceladus is 25-40 GW; the measured heat output from the South Polar Terrain (SPT) is 4-19 GW. The present-day SPT heat flux is of order 100 mWm-2, comparable to estimated paleo-heat fluxes for other regions of Enceladus. These regions have nominal ages of about 2 Ga, but the estimates are uncertain because the impactor flux in the Saturnian system may not resemble that elsewhere. Enceladuss measured rate of orbital expansion implies a low dissipation factor Qp for Saturn, with Qp≈3×103 (neglecting the role of Dione). This value implies that Enceladuss present-day equilibrium tidal heat production (roughly 50 GW, but with large uncertainties) is in approximate balance with its heat loss. If Qp is constant, Enceladus cannot be older than 1.5 Gyr (because otherwise it would have migrated more than is permissible). However, Saturns dissipation may be better described by the resonance-locking theory, in which case Enceladuss orbit may have only evolved outwards by about 35% over the age of the Solar System. In the constant-Qp scenario, any ancient tidal heating events would have been too energetic to be consistent with the observations. Because resonance-locking makes capture into earlier mean-motion orbital resonances less likely, the inferred ancient heating episodes probably took place when the current orbital resonance was already established. In the resonance-locking scenario, tidal heating did not change significantly over time, allowing for a long-lived ocean and a relatively stable ice shell. If so, Enceladus is an attractive target for future exploration from a habitability standpoint.

Published

2023

41. Optimizing image processing for modern wide field surveys: enhanced data management based on the LSST science pipelines.

Author

Hong, Yuanyu, Yang, Chao, Zhang, Miaomiao, Chen, Yanpeng, Liu, Binyang, Luo, Wentao, and Yao, Ji

Subjects

*DATABASE management, *IMAGE processing, *FIELD research, *BATCH processing, *ELECTRONIC data processing, *DIGITAL image processing, *MIDDLEWARE, *PIPELINES

Abstract

Introduction: In recent decades, numerous large survey projects have been initiated to enhance our understanding of the cosmos. Among these, the Vera C. Rubin Observatory's Legacy Survey of Space and Time (LSST) stands out as a flagship project of the Stage IV cosmology imaging surveys, offering an open-source framework for data management and processing adaptable to various instruments. Methods: In this paper, we introduce the 'obs_mccd' software package, designed to serve as a bridge linking raw data from generic mosaic-CCD instruments to the LSST data management framework. The package also facilitates the deployment of tailored configurations to the pipeline middleware. To validate our data processing pipeline, we processed a batch of realistic data from a commissioning wide-field telescope. Results: We established a prototype of the quality control (QC) system capable of assessing image quality parameters such as PSF size, ellipticity, and astrometric calibration. Our findings indicate that using a fifth-order polynomial for astrometric calibration effectively characterizes geometric distortion, achieving a median average geometric distortion residual of 0.011 pixel. Discussion: When comparing the performance of our pipeline to our inhouse pipeline applied to the same dataset, we observed that our new 'obs_mccd' pipeline offers improved precision, reducing the median average geometric distortion residual from 0.016 pixel to 0.011 pixel. This enhancement in performance underscores the benefits of the obs_mccd package in managing and processing data from wide-field surveys, and it opens up new avenues for scientific exploration with smaller, flexible survey systems complementing the LSST. [ABSTRACT FROM AUTHOR]

Published

2024

42. Astrometric detection of a Neptune-mass candidate planet in the nearest M-dwarf binary system GJ65 with VLTI/GRAVITY.

Author

GRAVITY Collaboration, Abuter, R., Amorim, A., Benisty, M., Berger, J. P., Bonnet, H., Bourdarot, G., Bourget, P., Brandner, W., Clénet, Y., Davies, R., Delplancke-Ströbele, F., Dembet, R., Drescher, A., Eckart, A., Eisenhauer, F., Feuchtgruber, H., Finger, G., Förster Schreiber, N. M., and Garcia, P.

Subjects

*PLANETARY orbits, *GRAVIMETRY, *ORBITS (Astronomy), *ASTROMETRY, *GROUND motion, *GRAVITY, *PLANETARY science

Abstract

The detection of low-mass planets orbiting the nearest stars is a central stake of exoplanetary science, as they can be directly characterized much more easily than their distant counterparts. Here, we present the results of our long-term astrometric observations of the nearest binary M-dwarf Gliese 65 AB (GJ65), located at a distance of only 2.67 pc. We monitored the relative astrometry of the two components from 2016 to 2023 with the VLTI/GRAVITY interferometric instrument. We derived highly accurate orbital parameters for the stellar system, along with the dynamical masses of the two red dwarfs. The GRAVITY measurements exhibit a mean accuracy per epoch of 50−60 ms in 1.5 h of observing time using the 1.8 m Auxiliary Telescopes. The residuals of the two-body orbital fit enable us to search for the presence of companions orbiting one of the two stars (S-type orbit) through the reflex motion they imprint on the differential A–B astrometry. We detected a Neptune-mass candidate companion with an orbital period of p = 156 ± 1 d and a mass of mp = 36 ± 7 M⊕. The best-fit orbit is within the dynamical stability region of the stellar pair. It has a low eccentricity, e = 0.1 − 0.3, and the planetary orbit plane has a moderate-to-high inclination of i > 30° with respect to the stellar pair, with further observations required to confirm these values. These observations demonstrate the capability of interferometric astrometry to reach microarcsecond accuracy in the narrow-angle regime for planet detection by reflex motion from the ground. This capability offers new perspectives and potential synergies with Gaia in the pursuit of low-mass exoplanets in the solar neighborhood. [ABSTRACT FROM AUTHOR]

Published

2024

43. HD 7977 and its possible influence on Solar System bodies.

Author

Dybczyński, Piotr A., Królikowska, Małgorzata, Bartczak, Przemysław, Podlewska-Gaca, Edyta, Kamiński, Krzysztof, Tokarek, Jakub, Langner, Krzysztof, and de Bruijne, Jos

Subjects

*SOLAR system, *STARS, *STELLAR mass, *NUMERICAL integration, *ORBITS (Astronomy), *ASTROMETRY

Abstract

Context. In the latest Gaia third data release, one can find extremely small proper motion components for the star HD 7977. This, together with the radial velocity measurement lead to the conclusion that this star passed very close to the Sun in the recent past. Aims. Such a very close approach of a one solar mass star must have resulted in noticeable changes in the motion of all Solar System bodies, especially those on less tight orbits, namely long-period comets (LPCs) and transneptunian objects (TNOs). We estimate and discuss these effects. Methods. Our current knowledge on the solar neighbourhood found in the latest Gaia catalogues allowed us to perform numerical integrations and prepare a list of potential stellar perturbers of LPCs. We used this list, made available in the StePPeD database. To study the past motion of LPCs under the simultaneous action of the Galactic potential and passing stars, we used precise original cometary orbits taken from the current CODE catalogue. Results. We examined the reliability of the extremely small proper motion of HD 7977 and conclude that this star can be an unresolved binary; however, according to the astrometry covering more than a century, the current Gaia data cannot be ruled out. We present the parameters of a very close passage of this star near the Sun. We also show examples of the strong influence of this passage on the past motion of some LPCs. We also discuss the possible influence of this perturber on other Solar System bodies. Conclusions. It is possible that 2.47 Myr ago the one solar mass star HD 7977 passed as close as 1000 au from the Sun. Such an event constitutes a kind of dynamical horizon for all studies of the past Solar System bodies' dynamics. [ABSTRACT FROM AUTHOR]

Published

2024

44. Hypervelocity star candidates from Gaia DR2 and DR3 proper motions and parallaxes.

Author

Scholz, R.-D.

Subjects

*STARS, *PARALLAX, *HYPERVELOCITY, *QUALITY control, *SUPERMASSIVE black holes, *ASTROMETRY

Abstract

Context. Hypervelocity stars (HVSs) unbound to the Galaxy can be formed with extreme stellar interactions, for example close encounters with supermassive black holes or in massive star clusters, supernova explosions in binary systems, or the stripping of dwarf galaxies. Observational evidence comes from measurements of radial velocities (RVs) of objects crossing the outer Galactic halo and of tangential velocities based on high proper motions (HPMs) and distances of relatively nearby stars. Aims. I searched for new nearby HVS candidates and reviewed known objects using their Gaia astrometric measurements. Methods. Candidates were selected with significant Gaia parallaxes of >0.1mas, proper motions of >20 mas yr−1, and computed galactocentric tangential velocities vtan_g>500 km s−1. The DR2 and DR3 samples of several thousand HVS candidates were studied with respect to their proper motions, sky distribution, number of observations, location in crowded fields, colour-magnitude diagrams, selection effects with magnitude, and RVs in DR3. The 72 most extreme (vtan_g>700 km s−1) and nearest (within 4kpc) DR3 HVS candidates were investigated with respect to detected close neighbours, flags, and astrometric quality parameters of objects of similar magnitudes in DR3. The quality checks involved HPM objects in a global comparison and all objects in the vicinity of each target. Results. Spurious HPMs in the Galactic centre region led to false HVS interpretations in Gaia DR2 and are still present in DR3, although to a lesser extent. Otherwise there is good agreement between the HPMs of HVS candidates in DR2 and DR3. However, HVS candidates selected from DR2 tend to have larger parallaxes, and hence lower tangential velocities in DR3. Most DR3 RVs are much lower than the tangential velocities, indicating that the DR3 HVS candidates are still affected by underestimated parallaxes. None of the 72 extreme nearby DR3 HVS candidates, including three D6 stars, passed all the quality checks. Their tangential velocities may turn out to be lower, but at least some of them still appear unbound to the Galaxy. [ABSTRACT FROM AUTHOR]

Published

2024

45. Near-infrared spectroscopic characterisation of Gaia ultra-cool dwarf candidates: Spectral types and peculiarities.

Author

Ravinet, T., Reylé, C., Lagarde, N., Burgasser, A., Smart, R. L., Moya, W. H., Marocco, F., Scholz, R.-D., Cooper, W. J., Cruz, K. L., Fernández-Trincado, J. G., Homeier, D., and Sarro, L. M.

Subjects

*LOW mass stars, *HABITABLE planets, *COOL stars (Astronomy), *ASTROMETRY, *BROWN dwarf stars, *NEIGHBORHOODS, *DWARF stars

Abstract

Context. The local census of very low-mass stars and brown dwarfs is crucial to improving our understanding of the stellar-substellar transition and their formation history. These objects, known as ultra-cool dwarfs (UCDs), are essential targets for searches of potentially habitable planets. However, their detection poses a challenge because of their low luminosity. The Gaia survey has identified numerous new UCD candidates thanks to its large survey and precise astrometry. Aims. We aim to characterise 60 UCD candidates detected by Gaia in the solar neighbourhood with a spectroscopic follow-up to confirm that they are UCDs, as well as to identify peculiarities. Methods. We acquired the near-infrared (NIR) spectra of 60 objects using the SOFI spectrograph between 0.93 and 2.5 µm (R~ 600). We identified their spectral types using a template-matching method. Their binarity is studied using astrometry and spectral features. Results. We confirm that 60 objects in the sample have ultra-cool dwarf spectral types close to those expected from astrometry. Their NIR spectra reveal that seven objects could host an unresolved coolest companion and seven UCDs share the same proper motions as other stars. The characterisation of these UCDs is part of a coordinated effort to improve our understanding of the Solar neighbourhood. [ABSTRACT FROM AUTHOR]

Published

2024

46. Numerical model of Phobos' motion incorporating the effects of free rotation.

Author

Yang, Yongzhang, Yan, Jianguo, Jian, Nianchuan, Matsumoto, Koji, and Barriot, Jean-Pierre

Subjects

*ROTATIONAL motion, *EULER equations (Rigid dynamics), *EQUATIONS of motion, *MARTIAN exploration, *LUNAR exploration, *SYMBOLIC computation

Abstract

Context. High-precision ephemerides are not only useful in supporting space missions, but also in investigating the physical nature of celestial bodies. This paper reports an update to the orbit and rotation model of the Martian moon Phobos. In contrast to earlier numerical models, this paper details a dynamical model that fully considers the rotation of Phobos. Here, Phobos' rotation is first described by Euler's rotational equations and integrated simultaneously with the orbital motion equations. We discuss this dynamical model, along with the differences with respect to the model now in use. Aims. This work is aimed at updating the physical model embedded in the ephemerides of Martian moons, considering improvements offered by exploiting high-precision observations expected from future missions (e.g., Japanese Martian Moons exploration, MMX), which fully supports future studies of the Martian moons. Methods. The rotational motion of Phobos can be expressed by Euler's rotational equations and integrated in parallel with the equations of the orbital motion of Phobos around Mars. In order to investigate the differences between the two models, we first reproduced and simulated the dynamical model that is now used in the ephemerides, but based on our own parameters. We then fit the model to the newest Phobos ephemeris published by Institut de Mécanique Céleste et de Calcul des Éphémérides (IMCCE). Based on our derived variational equations, the influence of the gravity field, the Love number, k2, and the rotation behavior were studied by fitting the full model to the simulated simple model. Our revised dynamic model for Phobos was constructed as a general method that can be extended with appropriate corrections (mainly rotation) to systems other than Phobos, such as the Saturn and Jupiter systems. Results. We present the variational equation for Phobos' rotation employing the symbolic Maple computation software. The adjustment test simulations confirm the latitude libration of Phobos, suggesting gravity field coefficients obtained using a shape model and homogeneous density hypothesis should be re-examined in the future in the context of dynamics. Furthermore, the simulations with different k2 values indicate that it is difficult to determine k2 efficiently using the current data. [ABSTRACT FROM AUTHOR]

Published

2024

47. The Gaia view on massive stars: EDR3 and what to expect from DR3.

Author

Maíz Apellániz, Jesús, Barbá, Rodolfo H., Pantaleoni González, Michelangelo, Weiler, Michael, Reed, B. Cameron, Fernández Aranda, Román, Crespo Bellido, Pablo, Sota, Alfredo, Alfaro, Emilio J., and Molina Lera, J. Alejo

Subjects

*STELLAR dynamics, *SUPERGIANT stars, *STARS, *OPEN clusters of stars, *DATA release

Abstract

At the time of this meeting, the latest Gaia data release is EDR3, published on 3 December 2020, but the next one, DR3, will appear soon, on 13 June 2022. This contribution describes, on the one hand, Gaia EDR3 results on massive stars and young stellar clusters, placing special emphasis on how a correct treatment of the astrometric and photometric calibration yields results that are simultaneously precise and accurate. On the other hand, it gives a brief description of the exciting results we can expect from Gaia DR3. [ABSTRACT FROM AUTHOR]

Published

2024

48. Centering algorithm of an unresolved primary and satellite system.

Author

Hao, J. N., Peng, Q. Y., and Guo, B. F.

Subjects

*DWARF planets, *ALGORITHMS, *BINARY stars, *PHOTOPLETHYSMOGRAPHY, *ATMOSPHERE, *PLANETARY observations

Abstract

Affected by the Earth's atmosphere, the image of a primary and satellite system may appear unresolved, such as the dwarf planet Haumea system. It is found by experiments that neither the two-dimensional Gaussian nor modified moment centering algorithms can accurately measure the photocenter of an image of unresolved primary and satellite system observed. This work investigates a specific centering algorithm to accurately measure the photocenter, which would be helpful to derive some physical parameters (e.g. orbital parameters and mass). Taking the dwarf planet Haumea and its brighter satellite Hi'iaka as an example, we simulate the motion of the photocenter with different seeings. We find that the photocenter of system changes significantly with seeings (∼0.074″ with the different seeings of 1″ and 3″) when using the two-dimensional Gaussian centering algorithm. However, the modified moment centering algorithm can accurately measure the photocenter of system without noises, but when noises are added its accuracy will be greatly influenced by noises. In this work, a new centering algorithm is proposed, which can accurately measure the photocenter with less influence of seeings and noises. Observations of dwarf planet Haumea taken over 25 nights are used to test the effectiveness of our proposed method. Compared with using two-dimensional Gaussian centering algorithm, the fitted parameter is slightly more accurate with less positional fitting errors when using the proposed method in this work. This method can also be applied to the centering of binary stars. [ABSTRACT FROM AUTHOR]

Published

2024

49. Metallicity and Kinematics of the Circumsolar Stellar Population of the Galaxy.

Author

Tutukov, A. V., Chupina, N. V., and Vereshchagin, S. V.

Subjects

*STARS, *STELLAR populations, *IRON clusters, *TRIPLE stars, *BIOCHEMICAL genetics

Abstract

The study of the kinematics and genetics of stellar populations in the Galaxy continued within a sphere with a radius of 300 parsecs based on the Gaia catalog (AG300). The main attention is paid to the chemical composition and genetics of stars in the corona of the core (halo) of the Galaxy with highly elliptical orbits and stars with hyperbolic orbits from the vicinity of the Sun. The possible role of various mechanisms of acceleration of the spatial motion of stars in the formation of the stellar corona (halo) of the Galaxy and stars with high hyperbolic ( > 500 km/s) velocities in the vicinity of the Sun is considered. Supernova explosions in close binaries and the disintegration of unstable close triple stars have been proposed as possible mechanisms for the acceleration of these stars. The abundance of iron in corona stars coincides with the abundance of iron in globular clusters, which is an argument in favor of their relationship. It is shown that about 7% of low metallicity stars ([Fe/H] < 3), judging by the position of their apexes, may belong to the "first" stars of the Galaxy, or they are products of the decay of low-mass satellites of the Galaxy. [ABSTRACT FROM AUTHOR]

Published

2024

50. Geometry-driven and dark-matter-sustained Milky Way rotation curves with Gaia DR3.

Author

Beordo, William, Crosta, Mariateresa, Lattanzi, Mario G, Re Fiorentin, Paola, and Spagna, Alessandro

Subjects

*MILKY Way, *ROTATIONAL motion, *STARS, *DARK matter, *GENERAL relativity (Physics), *ASTRONOMICAL perturbation, *ASTROMETRY

Abstract

Thanks to Gaia DR2, we proved for the first time that a general relativistic Milky Way rotation curve is statistically indistinguishable from its state-of-the-art dark matter analogue. Those results supported the ansatz that gravitational dragging can explain the observed flatness of the Milky Way rotation curve with a consistent radial matter density profile. To challenge again such a scenario, we select 719 143 young disc stars within | z | < 1 kpc and up to R ≃ 19 kpc from Gaia DR3 providing a much larger sample of high-quality astrometric and spectrophotometric data of unprecedented homogeneity. This sample comprises 241 918 OBA stars, 475 520 RGB giants, and 1705 Cepheides that we use to fit, as with DR2, both a classical velocity profile model, i.e. with a dark matter halo, and a general relativistic analogue derived from a dust disc-scale metric. Once more, further corroborating our earlier findings, both models are found to explain, with similar statistical quality, the new observed rotational velocities derived from different combinations of the selected sets of stars belonging to the disc of our Galaxy. The geometrical effect is found to drive the velocity profile from 10 kpc outwards, while being responsible for ∼30–37 per cent of this profile already at the Sun distance, similarly to the halo contribution in the classical model. This confirms our previous results on the contribution of Einstein's geometry and pushes to further investigate the role of General Relativity in tracing the Milky Way rotation curve; notably, the origin of this gravitational dragging remains undetermined, necessitating a dedicated in-depth exploration. [ABSTRACT FROM AUTHOR]

Published

2024