J. C. Raymond scite author profile

New X-ray observatories (Chandra and XMM-Newton) are providing a wealth of high-resolution X-ray spectra in which hydrogen-and helium-like ions are usually strong features. We present results from a new collisional-radiative plasma code, the Astrophysical Plasma Emission Code (apec), which uses atomic data in the companion Astrophysical Plasma Emission Database (aped) to calculate spectral models for hot plasmas. aped contains the requisite atomic data such as collisional and radiative rates, recombination cross sections, dielectronic recombination rates, and satellite line wavelengths. We compare the apec results to other plasma codes for hydrogen-and helium-like diagnostics, and test the sensitivity of our results to the number of levels included in the models. We find that dielectronic recombination with hydrogen-like ions into high (n = 6 − 10) principal quantum numbers affects some helium-like line ratios from low-lying (n = 2) transitions.

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Soft X-ray spectrum of a hot plasma

Raymond¹,

Smith²

1977

ApJS

1,324

1,001

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Iron ionization and recombination rates and ionization equilibrium

Arnaud¹,

Raymond²

1992

ApJ

644

607

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Radiative bow shock models of Herbig-Haro objects

Hartigan¹,

Raymond²,

Hartmann³

1987

ApJ

482

531

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The Accretion Disk Wind in the Black Hole GRO J1655−40

Miller

Raymond

Reynolds

et al. 2008

ApJ

182

367

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We report on simultaneous Chandra HETGS and RXTE observations of the transient stellar-mass black hole GRO J1655À40, made during its 2005 outburst. Chandra reveals a line-rich X-ray absorption spectrum consistent with a disk wind. Prior modeling of the spectrum suggested that the wind may be magnetically driven, potentially providing insights into the nature of disk accretion onto black holes. In this paper, we present results obtained with new models for this spectrum, generated using three independent photoionization codes: XSTAR, Cloudy, and our own code. Fits to the spectrum in particular narrow wavelength ranges, in evenly spaced wavelength slices, and across a broad wavelength band all strongly prefer a combination of high density, high ionization, and small inner radius. Indeed, the results obtained from all three codes require a wind that originates more than 10 times closer to the black hole and carrying a mass flux that is on the order of 1000 times higher than predicted by thermal driving models. If seminal work on thermally driven disk winds is robust, magnetic forces may play a role in driving the disk wind in GRO J1655À40. However, even these modeling efforts must be regarded as crude given the complexity of the spectra. We discuss these results in the context of accretion flows in black holes and other compact objects.

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J. C. Raymond

Collisional Plasma Models with APEC/APED: Emission-Line Diagnostics of Hydrogen-like and Helium-like Ions

Soft X-ray spectrum of a hot plasma

Iron ionization and recombination rates and ionization equilibrium

Radiative bow shock models of Herbig-Haro objects

The Accretion Disk Wind in the Black Hole GRO J1655−40

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