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FUSE spectroscopy of cool PG1159 Stars Elke Reiff (IAAT) Klaus Werner, Thomas Rauch (IAAT) Jeff Kruk (JHU Baltimore) Lars Koesterke (University of Texas) Hydrogen-Deficient Stars, Tübingen, September 18 th 2007. Observations. Observations obtained with FUSE
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FUSE spectroscopy of cool PG1159 Stars Elke Reiff (IAAT) Klaus Werner, Thomas Rauch (IAAT) Jeff Kruk (JHU Baltimore) Lars Koesterke (University of Texas) Hydrogen-Deficient Stars, Tübingen, September 18th 2007
Observations • Observations obtained with FUSE • 905 – 1187 Å (R ≈ 10000 – 20000 ≈ 0.1Å) • Rowland spectrograph: • 4 gratings and 2 detectors, • 2 coatings (Lithium-Fluoride, Silicon-Carbide) • Data reduction: • standard Calfuse Pipeline, done by J.W. Kruk • shifted to rest wavelength of photospheric lines • corrections for interstellar reddening EB-V and NH
Static Models • Modelling of the stellar atmosphere • NLTE model atmospheres, using TMAP • basic assumptions: • plane-parallel geometry, homogeneous structure • hydrostatic equilibrium (matter is at rest) • radiative equilibrium (no convection) • statistical equilibrium / rate equations (NLTE) • particle and charge conservation
Static Models • Detailed analysis of 2 „cool“ PG1159 stars • PG1424+535 (110 kK, log g = 7.0) • PG1707+427 (85 kK, log g = 7.5) • literature values for Teff and log g • literature values for abundances • models comprise He, C, N, O, Ne • analysis of light metals F, Si, S, P • analysis of Fe and Ni upper abundance limits
Static Models • Beyond light metals: including iron and nickel • too many levels and lines for numerical treatment • concept: combine energy levels to few „superlevels“ • lines are combined to transitions between bands • POS lines: observed; precisely known wavelengths • LIN lines: observed + theoretically predicted • IrOnIc (Iron Opacity Interface)
Static Models • Iron group elements in PG1159 stars • strong depletion of iron found, e.g. in the prototype • PG 1159-035 (Jahn et al. 2007) • iron depletion might be due to transformation • into heavier elements by s-process neutron capture • upper limit for nickel abundance still uncertain • POS lines for the final synthetic spectrum • upper limits for Fe and Ni abundance determined
Static Models • Fe VII in PG1424+535 • Teff = 110kK, log g 7.0 • POS lines of Fe VII used • upper limit of the iron • abundance is 0.1 x solar • (compared to 0.01 x solar • and solar abundance) • Fe ≲ 0.1 x solar abund.
Static Models • Fe VI in PG1707+427 • Teff = 85kK, log g 7.5 • POS lines of Fe VI used • upper limit of the iron • abundance is about solar • (compared to 0.1 x solar • and 10 x solar) • Fe ≲ solar abundance
Static Models • Ni VI in PG1707+427 • Teff = 85kK, log g 7.5 • POS lines of Ni VI used • upper limit of the nickel • abundance is about solar • (compared to 0.1 x solar • and 10 x solar) • Ni ≲ solar abundance
Summary • Analyses with static stellar atmospheres • upper limits for Fe and Ni abundance determined • depletion for Fe observable • but no enrichment of Ni detectable • origin of Fe-depletion not yet understood
Wind Models • Six objects in the sample of PG1159 stars show • strong P Cygni wind profiles in their spectra: • RXJ 2117.1+3412 (170kK, log g 6.0) • NGC 246 (150kK, log g 5.7) • K 1-16 (140kK, log g 6.4) • Abell 78 (110kK, log g 5.5) • NGC 7094 / Abell 43 (110 kK, log g 5.7) • Static models do not reproduce P Cygni profiles • Analysis with wind models required
Wind Models • Modelling of expanding stellar atmospheres • characteristic parameters • Teff, log g, L R, M • mass loss rate M • terminal velocity v∞ and velocity field v(r) • using wind-code of Lars Koesterke • spherically expanding atmosphere (1D) • homogeneous and stationary wind • wind models include H, He, C, N, O, Ne, F ·
Wind Models Previous analyses investigated… but spectra show also P Cygni profiles of…
Wind Models Ne VII @ 973 Å
Wind Models F VI @ 1139 Å
Summary • Analyses with static stellar atmospheres • upper limits for Fe and Ni abundance determined • depletion for Fe observable • but no enrichment of Ni detectable • origin of Fe-depletion not yet understood • Analyses with expanding stellar atmospheres • P Cygni wind profiles for trace elements Ne and F • determine and confirm abundances • see following talk by Marc Ziegler
Static Models • Modelling of the stellar atmosphere • NLTE model atmospheres, using TMAP • basic assumptions: • plane-parallel geometry, homogeneous structure • hydrostatic equilibrium (matter is at rest) • radiative equilibrium (no convection) • statistical equilibrium / rate equations (NLTE) • particle and charge conservation • solve radiative transfer equation