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|Title:||An abundance analysis from the STIS-HST UV spectrum of the non-magnetic Bp star HR 6000||Authors:||Castelli, F.
Cowley, C. R.
Ayres, T. R.
|Issue Date:||2017||Journal:||ASTRONOMY & ASTROPHYSICS||Number:||601||First Page:||A119||Abstract:||Context. The sharp-line spectrum of the non-magnetic, main-sequence Bp star HR 6000 has peculiarities that distinguish it from those of the HgMn stars with which it is sometimes associated. The position of the star close to the center of the Lupus 3 molecular cloud, whose estimated age is on the order of 9.1 ± 2.1 Myr, has lead to the hypothesis that the anomalous peculiarities of HR 6000 can be explained by the young age of the star. <BR /> Aims: Observational material from the Hubble Space Telescope (HST) provides the opportunity to extend the abundance analysis previously performed for the optical region and clarify the properties of this remarkable peculiar star. Our aim was to obtain the atmospheric abundances for all the elements observed in a broad region from 1250 to 10 000 Å. <BR /> Methods: An LTE synthetic spectrum was compared with a high-resolution spectrum observed with the Space Telescope Imaging Spectrograph (STIS) equipment in the 1250-3040 Å interval. Abundances were changed until the synthetic spectrum fit the observed spectrum. The assumed model is an LTE, plane-parallel, line-blanketed ATLAS12 model already used for the abundance analysis of a high-resolution optical spectrum observed at ESO with the Ultraviolet and Visual Echelle Spectrograph (UVES). The stellar parameters are T<SUB>eff</SUB> = 13450 K, log g = 4.3, and zero microturbulent velocity. <BR /> Results: Abundances for 28 elements and 7 upper limits were derived from the ultraviolet spectrum. Adding results from previous work, we have now quantitative results for 37 elements, some of which show striking contrasts with those of a broad sample of HgMn stars. The analysis has pointed out numerous abundance anomalies, such as ionization anomalies and line-to-line variation in the derived abundances, in particular for silicon. The inferred discrepancies could be explained by non-LTE effects and with the occurrence of diffusion and vertical abundance stratification. In the framework of the last hypothesis, we obtained, by means of trial and error, empirical step functions of abundance versus optical depth log (τ<SUB>5000</SUB>) for carbon, nitrogen, silicon, manganese, and gold, while we failed to find such a function for phosphorous. The poor results for carbon, and mostly for phosphorus, suggest the possible importance in this star of NLTE effects to be investigated in future works.||URI:||http://hdl.handle.net/20.500.12386/26757||URL:||https://www.aanda.org/articles/aa/abs/2017/05/aa29854-16/aa29854-16.html||ISSN:||0004-6361||DOI:||10.1051/0004-6361/201629854||Bibcode ADS:||2017A&A...601A.119C||Fulltext:||open|
|Appears in Collections:||1.01 Articoli in rivista|
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checked on Jan 28, 2021
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