Your search keyword '"Chandra, Vedant"' showing total 4 results

1. Distant Echoes of the Milky Way's Last Major Merger.

Author

Chandra, Vedant, Naidu, Rohan P., Conroy, Charlie, Ji, Alexander P., Rix, Hans-Walter, Bonaca, Ana, Cargile, Phillip A., Han, Jiwon Jesse, Johnson, Benjamin D., Ting, Yuan-Sen, Woody, Turner, and Zaritsky, Dennis

Subjects

*MILKY Way, *MERGERS & acquisitions, *RED giants, *GALACTIC halos, *STELLAR spectra, *ORBITS (Astronomy)

Abstract

The majority of the Milky Way's stellar halo consists of debris from our galaxy's last major merger, the Gaia-Sausage-Enceladus (GSE). In the past few years, stars from the GSE have been kinematically and chemically studied in the inner 30 kpc of our galaxy. However, simulations predict that accreted debris could lie at greater distances, forming substructures in the outer halo. Here we derive metallicities and distances using Gaia DR3 XP spectra for an all-sky sample of luminous red giant stars, and map the outer halo with kinematics and metallicities out to 100 kpc. We obtain follow-up spectra of stars in two strong overdensities—including the previously identified outer Virgo Overdensity—and find them to be relatively metal rich and on predominantly retrograde orbits, matching predictions from simulations of the GSE merger. We argue that these are apocentric shells of GSE debris, forming 60–90 kpc counterparts to the 15–20 kpc shells that are known to dominate the inner stellar halo. Extending our search across the sky with literature radial velocities, we find evidence for a coherent stream of retrograde stars encircling the Milky Way from 50 to 100 kpc, in the same plane as the Sagittarius Stream but moving in the opposite direction. These are the first discoveries of distant and structured imprints from the GSE merger, cementing the picture of an inclined and retrograde collision that built up our galaxy's stellar halo. [ABSTRACT FROM AUTHOR]

Published

2023

2. Evidence from Disrupted Halo Dwarfs that r-process Enrichment via Neutron Star Mergers is Delayed by ≳500 Myr.

Author

Naidu, Rohan P., Ji, Alexander P., Conroy, Charlie, Bonaca, Ana, Ting, Yuan-Sen, Zaritsky, Dennis, Son, Lieke A. C. van, Broekgaarden, Floor S., Tacchella, Sandro, Chandra, Vedant, Caldwell, Nelson, Cargile, Phillip, and Speagle, Joshua S.

Published

2022

3. Searching for Low-mass Population III Stars Disguised as White Dwarfs.

Author

Chandra, Vedant and Schlaufman, Kevin C.

Published

2021

4. A Gravitational Redshift Measurement of the White Dwarf Mass–Radius Relation.

Author

Chandra, Vedant, Hwang, Hsiang-Chih, Zakamska, Nadia L., and Cheng, Sihao

Subjects

*GRAVITATIONAL effects, *REDSHIFT, *STELLAR mass, *WHITE dwarf stars, *EQUATIONS of state, *ASTRONOMICAL surveys, *STELLAR oscillations, *DOPPLER effect

Abstract

The mass–radius relation of white dwarfs is largely determined by the equation of state of degenerate electrons, which causes the stellar radius to decrease as mass increases. Here we observationally measure this relation using the gravitational redshift effect, a prediction of general relativity that depends on the ratio between stellar mass and radius. Using observations of over 3000 white dwarfs from the Sloan Digital Sky Survey and the Gaia space observatory, we derive apparent radial velocities from absorption lines, stellar radii from photometry and parallaxes, and surface gravities by fitting atmospheric models to spectra. By averaging the apparent radial velocities of white dwarfs with similar radii and, independently, surface gravities, we cancel out random Doppler shifts and measure the underlying gravitational redshift. Using these results, we empirically measure the white dwarf mass–radius relation across a wide range of stellar masses. Our results are consistent with leading theoretical models, and our methods could be used with future observations to empirically constrain white dwarf core composition and evolution. [ABSTRACT FROM AUTHOR]

Published

2020