19 research outputs found
Radial Velocity Confirmation of a Binary Detected from Pulse Timings
A periodic variation in the pulse timings of the pulsating hot subdwarf B
star CS 1246 was recently discovered via the O-C diagram and suggests the
presence of a binary companion with an orbital period of two weeks. Fits to
this phase variation, when interpreted as orbital reflex motion, imply CS 1246
orbits a barycenter 11 light-seconds away with a velocity of 16.6 km/s. Using
the Goodman spectrograph on the SOAR telescope, we decided to confirm this
hypothesis by obtaining radial velocity measurements of the system over several
months. Our spectra reveal a velocity variation with amplitude, period, and
phase in accordance with the O-C diagram predictions. This corroboration
demonstrates that the rapid pulsations of hot subdwarf B stars can be adequate
clocks for the discovery of binary companions via the pulse timing method.Comment: Accepted for publication in ApJ Letters; 5 pages, 2 figures, 3
tables; uses emulateap
The Solar Neighborhood. XXXIX. Parallax Results from the CTIOPI and NOFS Programs: 50 New Members of the 25 Parsec White Dwarf Sample
We present 114 trigonometric parallaxes for 107 nearby white dwarf (WD)
systems from both the Cerro Tololo Inter-American Observatory Parallax
Investigation (CTIOPI) and the U. S. Naval Observatory Flagstaff Station (NOFS)
parallax programs. Of these, 76 parallaxes for 69 systems were measured by the
CTIOPI program and 38 parallaxes for as many systems were measured by the NOFS
program. A total of 50 systems are confirmed to be within the 25 pc horizon of
interest. Coupled with a spectroscopic confirmation of a common proper motion
companion to a Hipparcos star within 25 pc as well as confirmation parallax
determinations for two WD systems included in the recently released Tycho Gaia
Astrometric Solution (TGAS) catalog, we add 53 new systems to the 25 pc WD
sample a 42% increase. Our sample presented here includes four strong
candidate halo systems, a new metal-rich DAZ WD, a confirmation of a recently
discovered nearby short-period (P = 2.85 hr) double degenerate, a WD with a new
astrometric pertubation (long period, unconstrained with our data), and a new
triple system where the WD companion main-sequence star has an astrometric
perturbation (P 1.6 yr).Comment: 32 pages, 12 figures. Figure 4 in the manuscript is a representative
set of plots - plots for all WDs presented here are available
(allfits_photo.pdf, allfits_photo_DQ.pdf, and allfits_photo_DZ.pdf). Accepted
for publication in The Astronomical Journa
A second case of outbursts in a pulsating white dwarf observed by Kepler
We present observations of a new phenomenon in pulsating white dwarf stars: large-amplitude outbursts at timescales much longer than the pulsation periods. The cool ( = 11,060 K), hydrogen-atmosphere pulsating white dwarf PG 1149+057 was observed nearly continuously for more than 78.8 day by the extended Kepler mission in K2 Campaign 1. The target showed 10 outburst events, recurring roughly every 8 day and lasting roughly 15 hr, with maximum flux excursions up to 45% in the Kepler bandpass. We demonstrate that the outbursts affect the pulsations and therefore must come from the white dwarf. Additionally, we argue that these events are not magnetic reconnection flares, and are most likely connected to the stellar pulsations and the relatively deep surface convection zone. PG 1149+057 is now the second cool pulsating white dwarf to show this outburst phenomenon, after the first variable white dwarf observed in the Kepler mission, KIC 4552982. Both stars have the same effective temperature, within the uncertainties, and are among the coolest known pulsating white dwarfs of typical mass. These outbursts provide fresh observational insight into the red edge of the DAV instability strip and the eventual cessation of pulsations in cool white dwarfs
Core crystallization and pile-up in the cooling sequence of evolving white dwarfs
White dwarfs are stellar embers depleted of nuclear energy sources that cool over billions of years. These stars, which are supported by electron degeneracy pressure, reach densities of 10^7 grams per cubic centimetre in their cores. It has been predicted that a first-order phase transition occurs during white-dwarf cooling, leading to the crystallization of the non-degenerate carbon and oxygen ions in the core, which releases a considerable amount of latent heat and delays the cooling process by about one billion years. However, no direct observational evidence of this effect has been reported so far. Here we report the presence of a pile-up in the cooling sequence of evolving white dwarfs within 100 parsecs of the Sun, determined using photometry and parallax data from the Gaia satellite. Using modelling, we infer that this pile-up arises from the release of latent heat as the cores of the white dwarfs crystallize. In addition to the release of latent heat, we find strong evidence that cooling is further slowed by the liberation of gravitational energy from element sedimentation in the crystallizing cores. Our results describe the energy released by crystallization in strongly coupled Coulomb plasmas, and the measured cooling delays could help to improve the accuracy of methods used to determine the age of stellar populations from white dwarfs
Kepler and TESS Observations of PG 1159-035
PG 1159-035 is the prototype of the DOV hot pre-white dwarf pulsators. It was
observed during the Kepler satellite K2 mission for 69 days in 59 s cadence
mode and by the TESS satellite for 25 days in 20 s cadence mode. We present a
detailed asteroseismic analysis of those data. We identify a total of 107
frequencies representing 32 l=1 modes, 27 frequencies representing 12 l=2
modes, and 8 combination frequencies. The combination frequencies and the modes
with very high k values represent new detections. The multiplet structure
reveals an average splitting of 4.0+/-0.4 muHz for l=1 and 6.8+/-0.2 muHz for
l=2, indicating a rotation period of 1.4+/-0.1 days in the region of period
formation. In the Fourier transform of the light curve, we find a significant
peak at 8.904+/-0.003 muHz suggesting a surface rotation period of
1.299+/-0.002 days. We also present evidence that the observed periods change
on timescales shorter than those predicted by current evolutionary models. Our
asteroseismic analysis finds an average period spacing for l=1 of 21.28+/-0.02
s. The l=2 modes have a mean spacing of 12.97+/-0.4 s. We performed a detailed
asteroseismic fit by comparing the observed periods with those of evolutionary
models. The best fit model has Teff=129600+/- 11100 K, mass M*=0.565+/-0.024
Msun, and log g=7.41+0.38-0.54, within the uncertainties of the spectroscopic
determinations. We argue for future improvements in the current models, e.g.,
on the overshooting in the He-burning stage, as the best-fit model does not
predict excitation for all the pulsations detected in PG~1159-03.Comment: 27 pages, 9 tables and 26 figure
A 1.05 M_☉ Companion to PSR J2222–0137: The Coolest Known White Dwarf?
The recycled pulsar PSR J2222–0137 is one of the closest known neutron stars (NSs) with a parallax distance of 267_(-0.9)^(+1.2) pc and an edge-on orbit. We measure the Shapiro delay in the system through pulsar timing with the Green Bank Telescope, deriving a low pulsar mass (1.20 ± 0.14 M_☉) and a high companion mass (1.05 ± 0.06 M_☉) consistent with either a low-mass NS or a high-mass white dwarf. We can largely reject the NS hypothesis on the basis of the system's extremely low eccentricity (3 × 10^(–4))—too low to have been the product of two supernovae under normal circumstances. However, despite deep optical and near-infrared searches with Southern Astrophysical Research and the Keck telescopes we have not discovered the optical counterpart of the system. This is consistent with the white dwarf hypothesis only if the effective temperature is <3000 K, a limit that is robust to distance, mass, and atmosphere uncertainties. This would make the companion to PSR J2222–0137 one of the coolest white dwarfs ever observed. For the implied age to be consistent with the age of the Milky Way requires the white dwarf to have already crystallized and entered the faster Debye-cooling regime
Insights into internal effects of common-envelope evolution using the extended Kepler mission
We present an analysis of the binary and physical parameters of a unique pulsating white dwarf with a main-sequence companion, SDSS J1136+0409, observed for more than 77 d during the first pointing of the extended Kepler mission: K2 Campaign 1. Using new groundbased spectroscopy, we show that this post-common-envelope binary has an orbital period of 6.89760103(60) h, which is also seen in the photometry as a result of Doppler beaming and ellipsoidal variations of the secondary. We spectroscopically refine the temperature of the white dwarf to 12 330 ± 260 K and its mass to 0.601 ± 0.036 M. We detect seven independent pulsation modes in the K2 light curve. A preliminary asteroseismic solution is in reasonable agreement with the spectroscopic atmospheric parameters. Three of the pulsation modes are clearly rotationally split multiplets, which we use to demonstrate that the white dwarf is not synchronously rotating with the orbital period but has a rotation period of 2.49 ± 0.53 h. This is faster than any known isolated white dwarf, but slower than almost all white dwarfs measured in non-magnetic cataclysmic variables, the likely future state of this binary
I Spy Transits and Pulsations: Empirical Variability in White Dwarfs Using Gaia and the Zwicky Transient Facility
We present a novel method to detect variable astrophysical objects and
transient phenomena using anomalous excess scatter in repeated measurements
from public catalogs of Gaia DR2 and Zwicky Transient Facility (ZTF) DR3
photometry. We first provide a generalized, all-sky proxy for variability using
only Gaia DR2 photometry, calibrated to white dwarf stars. To ensure more
robust candidate detection, we further employ a method combining Gaia with ZTF
photometry and alerts. To demonstrate the efficacy, we apply this latter
technique to a sample of roughly white dwarfs within 200 pc centered
on the ZZ Ceti instability strip, where hydrogen-atmosphere white dwarfs are
known to pulsate. Through inspecting the top samples ranked by these
methods, we demonstrate that both the Gaia-only and ZTF-informed techniques are
highly effective at identifying known and new variable white dwarfs, which we
verify using follow-up, high-speed photometry. We confirm variability in all 33
out of 33 () observed white dwarfs within our top highest-ranked
candidates, both inside and outside the ZZ Ceti instability strip. In addition
to dozens of new pulsating white dwarfs, we also identify five white dwarfs
highly likely to show transiting planetary debris; if confirmed, these systems
would more than triple the number of white dwarfs known to host transiting
debris.Comment: 30 pages, 14 figures, revised and accepted to ApJ on March 11, 202
Baseline characteristics of patients in the reduction of events with darbepoetin alfa in heart failure trial (RED-HF)
<p>Aims: This report describes the baseline characteristics of patients in the Reduction of Events with Darbepoetin alfa in Heart Failure trial (RED-HF) which is testing the hypothesis that anaemia correction with darbepoetin alfa will reduce the composite endpoint of death from any cause or hospital admission for worsening heart failure, and improve other outcomes.</p>
<p>Methods and results: Key demographic, clinical, and laboratory findings, along with baseline treatment, are reported and compared with those of patients in other recent clinical trials in heart failure. Compared with other recent trials, RED-HF enrolled more elderly [mean age 70 (SD 11.4) years], female (41%), and black (9%) patients. RED-HF patients more often had diabetes (46%) and renal impairment (72% had an estimated glomerular filtration rate <60 mL/min/1.73 m2). Patients in RED-HF had heart failure of longer duration [5.3 (5.4) years], worse NYHA class (35% II, 63% III, and 2% IV), and more signs of congestion. Mean EF was 30% (6.8%). RED-HF patients were well treated at randomization, and pharmacological therapy at baseline was broadly similar to that of other recent trials, taking account of study-specific inclusion/exclusion criteria. Median (interquartile range) haemoglobin at baseline was 112 (106–117) g/L.</p>
<p>Conclusion: The anaemic patients enrolled in RED-HF were older, moderately to markedly symptomatic, and had extensive co-morbidity.</p>