Stephan R. McCandliss scite author profile

We have used archival far-ultraviolet spectra from observations made by HST STIS and FUSE to determine the column densities and rotational excitation temperatures for carbon monoxide and molecular hydrogen, respectively, along 23 sight lines to Galactic O and B stars. The reddening values range from E(B À V ) ¼ 0:07 to 0.62, sampling the diffuse to translucent interstellar medium (ISM ). We find that the H 2 column densities range from 5 ; 10 18 to 8 ; 10 20 cm À2 and the CO from upper limits around 2 ; 10 12 cm À2 to detections as high as 1:4 ; 10 16 cm À2 . CO increases with increasing H 2 , roughly following a power law of factor $2. The CO/ H 2 column density ratio is thus not constant, ranging from 10 À 7 to 10 À5 , with a mean value of 3 ; 10 À6 . The sample segregates into ''diffuse'' and ''translucent'' regimes, the former with molecular fraction P0.25 and A V /d < 1 mag kpc À1 . The mean CO/ H 2 for these two regimes are 3:6 ; 10 À7 and 9:3 ; 10 À6 , respectively, significantly lower than the canonical dark cloud value of 10 À4 . Six sight lines show the isotopic variant 13 CO, and the isotopic ratio we observe ($50Y70) is consistent with, if perhaps a little below, the average 12 C/ 13 C for the ISM at large. The average H 2 rotational excitation temperature is 74 AE 24 K, agreeing well with previous studies, and the average CO temperature is 4.1 K, with some sight lines showing temperatures as high as 6.4 K. The higher excitation CO is observed with higher column densities, consistent with the effects of photon trapping in clouds with densities in the 20Y100 cm À3 range. We discuss the implications for the structure of the diffuse/translucent regimes of the ISM and the estimation of molecular mass in galaxies.

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A “Combination Nova” Outburst in Z Andromedae: Nuclear Shell Burning Triggered by a Disk Instability

Sokoloski

Kenyon

Espey

et al. 2006

ApJ

103

194

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We describe observational evidence for a new kind of interacting-binary-star outburst that involves both an accretion instability and an increase in thermonuclear shell burning on the surface of an accreting white dwarf. We refer to this new type of eruption as a combination nova. In late 2000, the prototypical symbiotic star Z Andromedae brightened by roughly two magnitudes in the optical. We observed the outburst in the radio with the VLA and MERLIN, in the optical both photometrically and spectroscopically, in the far ultraviolet with F U SE, and in the X-rays with both Chandra and XM M . The two-year-long event had three distinct stages. During the first stage, the optical rise closely resembled an earlier, small outburst that was caused by an accretion-disk instability. In the second stage, the hot component ejected an optically thick shell of material. In the third stage, the shell cleared to reveal a white dwarf whose luminosity remained on the order of 10 4 L ⊙ for approximately one year. The eruption was thus too energetic to have been powered by accretion alone. We propose that the initial burst of accretion was large enough to trigger enhanced nuclear burning on the surface of the white dwarf and the ejection of an optically thick shell of material. This outburst therefore combined elements of both a dwarf nova and a classical nova. Our results have implications for the long-standing problem of producing shell flashes with short recurrence times on low-mass white dwarfs in symbiotic stars.

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The Low-redshift Lyman Continuum Survey. II. New Insights into LyC Diagnostics

Flury¹,

Jaskot²,

Ferguson³

et al. 2022

ApJ

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The Lyman continuum (LyC) cannot be observed at the epoch of reionization (z ≳ 6) owing to intergalactic H i absorption. To identify LyC emitters (LCEs) and infer the fraction of escaping LyC, astronomers have developed various indirect diagnostics of LyC escape. Using measurements of the LyC from the Low-redshift Lyman Continuum Survey (LzLCS), we present the first statistical test of these diagnostics. While optical depth indicators based on Lyα, such as peak velocity separation and equivalent width, perform well, we also find that other diagnostics, such as the [O iii]/[O ii] flux ratio and star formation rate surface density, predict whether a galaxy is an LCE. The relationship between these galaxy properties and the fraction of escaping LyC flux suggests that LyC escape depends strongly on H i column density, ionization parameter, and stellar feedback. We find that LCEs occupy a range of stellar masses, metallicities, star formation histories, and ionization parameters, which may indicate episodic and/or different physical causes of LyC escape.

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A highly magnified star at redshift 6.2

Welch

Coe

Diego

et al. 2022

Nature

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Galaxy clusters magnify background objects through strong gravitational lensing. Typical magnifications for lensed galaxies are factors of a few but can also be as high as tens or hundreds, stretching galaxies into giant arcs 1;2 . Individual stars can attain even higher magnifications given fortuitous alignment with the lensing cluster. Recently, several individual stars at redshift z ∼ 1 − 1.5 have been discovered, magnified by factors of thousands, temporarily boosted by microlensing 3;4;5;6 . Here we report observations of a more distant and persistent magnified star at redshift z phot = 6.2 ± 0.1, 900 Myr after the Big Bang. This star is magnified by a factor of thousands by the foreground galaxy cluster lens

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The interstellar N2 abundance towards HD 124314 from far-ultraviolet observations

Knauth

Andersson

McCandliss

et al. 2004

Nature

111

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The abundance of interstellar molecular nitrogen (N2) is of considerable importance: models of steady-state gas-phase interstellar chemistry, together with millimetre-wavelength observations of interstellar N2H+ in dense molecular clouds predict that N2 should be the most abundant nitrogen-bearing molecule in the interstellar medium. Previous attempts to detect N2 absorption in the far-ultraviolet or infrared (ice features) have hitherto been unsuccessful. Here we report the detection of interstellar N2 at far-ultraviolet wavelengths towards the moderately reddened star HD 124314 in the constellation of Centaurus. The N2 column density is larger than expected from models of diffuse clouds and significantly smaller than expected for dense molecular clouds. Moreover, the N2 abundance does not explain the observed variations in the abundance of atomic nitrogen (N I) towards high-column-density sightlines, implying that the models of nitrogen chemistry in the interstellar medium are incomplete.

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