Weak metal lines in optical high-resolution Very Large Telescope and Keck spectra of “cool” PG 1159 stars

We present Li, Na, Al, and Fe abundances of 199 lower red giant branch star members of the stellar system Omega Centauri, using high-resolution spectra acquired with FLAMES at the Very Large Telescope. The A(Li) distribution is peaked at A(Li) ∼ 1 dex with a prominent tail towards lower values. The peak of the distribution well agrees with the lithium abundances measured in lower red giant branch stars in globular clusters and Galactic field stars. Stars with A(Li) ∼ 1 dex are found at metallicities lower than [Fe/H] ∼ –1.3 dex but they disappear at higher metallicities. On the other hand, Li-poor stars are found at all metallicities. The most metal-poor stars exhibit a clear Li–Na anti-correlation, where about 30% of the sample have A(Li) lower than ∼0.8 dex, while these stars represent a small fraction of normal globular clusters. Most of the stars with [Fe/H] > –1.6 dex are Li poor and Na rich. The Li depletion measured in these stars is not observed in globular clusters with similar metallicities and we demonstrate that it is not caused by the proposed helium enhancements and/or young ages. Hence, these stars formed from a gas already depleted in lithium. Finally, we note that Omega Centauri includes all the populations (Li-normal/Na-normal, Li-normal/Na-rich, and Li-poor/Na-rich stars) observed, to a lesser extent, in mono-metallic GCs.

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Interstellar Matter with Very Large Telescopes

International Astronomical Union Colloquium ◽

10.1017/s0252921100108772 ◽

1984 ◽

Vol 79 ◽

pp. 675-678

Author(s):

J. Lequeux

Keyword(s):

High Resolution ◽

Absorption Lines ◽

High Resolution Spectroscopy ◽

Interstellar Matter ◽

Large Telescope ◽

Interstellar Absorption ◽

Near Ir ◽

Very Large Telescope ◽

Large Telescopes ◽

Diffuse Matter

Interstellar matter is certainly one of the fields where a very large telescope (VLT) will prove to be most fruitful. This includes (somewhat paradoxically, but this will be explained later) the study of extended emissions. I will now examine in turn the different domains of interest for a VLT.I. Neutral diffuse matterOptical and near IR observations will mainly contribute to this domain through high-resolution spectroscopy of interstellar absorption lines in the spectra of stars. These lines are resonant lines of atoms (NaI, KI, etc.) or ions (CaII, TiII, etc.) as well as of some molecules (CH+, CH, CN, CS+, C2 in the near IR). Clearly this kind of study is always photon - limited; a VLT will collect more photons than present telescopes, thus increase the possibilities considerably.

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Speckle Interferometry, Speckle Masking, Speckle Spectroscopy and Speckle Frame Selection

International Astronomical Union Colloquium ◽

10.1017/s0252921100108498 ◽

1984 ◽

Vol 79 ◽

pp. 337-345 ◽

Cited By ~ 1

Author(s):

Gerd Weigelt

Keyword(s):

High Resolution ◽

Speckle Interferometry ◽

Large Telescope ◽

Speckle Imaging ◽

Frame Selection ◽

Very Large Telescope

AbstractHigh-resolution speckle imaging is one of the most fascinating possibilities of a Very Large Telescope (VLT). Various speckle methods can yield a resolution of about 0.01" with a 8-m to 10-m VLT. As exiting as the resolution is the limiting magnitude of the speckle methods. The limiting magnitude is extremely seeingdependent. The following limiting magnitudes are possible with speckle interferometry, speckle masking and speckle spectroscopy:4" seeing: limiting magnitude 152" seeing: limiting magnitude 17.51" seeing: limiting magnitude 20 (!)

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High-Resolution Spectroscopy from 3050 to 10000 Å of the Hubble Deep Field South QSO J2233−606 with UVES at the ESO Very Large Telescope

The Astronomical Journal ◽

10.1086/301575 ◽

2000 ◽

Vol 120 (4) ◽

pp. 1648-1653 ◽

Cited By ~ 18

Author(s):

S. Cristiani ◽

V. D’Odorico

Keyword(s):

High Resolution ◽

High Resolution Spectroscopy ◽

Large Telescope ◽

Very Large Telescope ◽

Hubble Deep Field

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A Flash in the Dark: UVES Very Large Telescope High‐Resolution Spectroscopy of Gamma‐Ray Burst Afterglows

The Astrophysical Journal ◽

10.1086/429385 ◽

2005 ◽

Vol 624 (2) ◽

pp. 853-867 ◽

Cited By ~ 62

Author(s):

F. Fiore ◽

V. D’Elia ◽

D. Lazzati ◽

R. Perna ◽

L. Sbordone ◽

...

Keyword(s):

High Resolution ◽

Gamma Ray ◽

High Resolution Spectroscopy ◽

Large Telescope ◽

Gamma Ray Burst ◽

Very Large Telescope

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Characterization of the Zonal Wind Flow in the Upper Atmosphere of Titan with the VLT

Highlights of Astronomy ◽

10.1017/s1539299600017457 ◽

2005 ◽

Vol 13 ◽

pp. 897-897

Author(s):

Régis Courtin ◽

David Luz ◽

Daniel Gautier ◽

Thierry Appourchaux ◽

Jean-Pierre Lebreton ◽

...

Keyword(s):

High Resolution ◽

Zonal Wind ◽

Upper Atmosphere ◽

Wind Flow ◽

Large Telescope ◽

Spectroscopic Observations ◽

Very Large Telescope

AbstractWe report on recent efforts to characterize the zonal wind flow in the upper atmosphere of Titan from high resolution spectroscopic observations with the Very Large Telescope.

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High resolution optical spectroscopy of the N2-rich comet C/2016 R2 (PanSTARRS)

Astronomy and Astrophysics ◽

10.1051/0004-6361/201834357 ◽

2019 ◽

Vol 624 ◽

pp. A64 ◽

Cited By ~ 9

Author(s):

C. Opitom ◽

D. Hutsemékers ◽

E. Jehin ◽

P. Rousselot ◽

F. J. Pozuelos ◽

...

Keyword(s):

High Resolution ◽

Isotopic Ratio ◽

Kuiper Belt ◽

Large Telescope ◽

Strong Emission ◽

Kuiper Belt Object ◽

Water Abundance ◽

Very Large Telescope ◽

First Time ◽

Ch Radical

Context. Early observations of comet C/2016 R2 (PanSTARRS) have shown that the composition of this comet is very peculiar. Radio observations have revealed a CO-rich and HCN-poor comet and an optical coma dominated by strong emission bands of CO+ and, more surprisingly, N2+. Aims. The strong detection of N2+ in the coma of C/2016 R2 provided an ideal opportunity to measure the 14N∕15N isotopic ratio directly from N2+ for the first time, and to estimate the N2∕CO ratio, which is an important diagnostic to constrain formation models of planetesimals, in addition to the more general study of coma composition. Methods. We obtained high resolution spectra of the comet in February 2018 when it was at 2.8 au from the Sun. We used the UVES spectrograph of the European Southern Observatory Very Large Telescope, complemented with narrowband images obtained with the TRAPPIST telescopes. Results. We detect strong emissions from the N2+ and CO+ ions, but also CO2+, emission lines from the CH radical, and much fainter emissions of the CN, C2, and C3 radicals that were not detected in previous observations of this comet. We do not detect OH or H2O+, and we derive an upper limit of the H2O+∕CO+ ratio of 0.4, implying that the comet has a low water abundance. We measure a N2+/CO+ ratio of 0.06 ± 0.01. The non-detection of NH2 indicates that most of the nitrogen content of the comet is in N2. Together with the high N2+/CO+ ratio, this could indicate a low formation temperature of the comet or that the comet is a fragment of a large differentiated Kuiper Belt object. The CO2+/CO+ ratio is 1.1 ± 0.3. We do not detect 14N15N+ lines and can only put a lower limit on the 14N∕15N ratio (measured from N2+) of about 100, which is compatible with measurements of the same isotopic ratio for NH2 and CN in other comets. Finally, in addition to the [OI] and [CI] forbidden lines, we detect for the first time the forbidden nitrogen lines [NI] doublet at 519.79 and 520.03 nm in the coma of a comet.

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