Recently X-ray photoabsorption in KLL resonances of O VI was predicted
[Pradhan, Astrophys.J. Lett. 545, L165 (2000)], and detected by the Chandra
X-ray Observatory [Lee et al, Astrophys. J. {\it Lett.}, submitted].
  The required resonance oscillator strengths f_r, are evaluated in terms of
the differential oscillator strength df/de that relates bound and continuum
absorption. We present the f_r values from radiatively damped and undamped
photoionization cross sections for Li-like C,O, and Fe calculated using
relativistic close coupling Breit-Pauli R-matrix method. The KLL resonances of
interest here are: 1s2p (^3P^o) 2s [^4P^o_{1/2,3/2}, ^2P^o_{1/2,3/2}] and 1s2p
(^1P^o) 2s [^2P^o_{1/2,3/2}]. The KLL photoabsorption resonances in Fe XXIV are
fully resolved up to natural autoionization profiles for the first time. It is
demonstrated that the undamped f_r independently yield the resonance radiative
decay rates, and thereby provide a precise check on the resolution of
photoionization calculations in general. The predicted photoabsorption features
should be detectable by the X-ray space observatories and enable column
densities in highly ionized astrophysical plasmas to be determined from the
calculated f_r. The dielectronic satellites may appear as redward broadening of
resonances lines in emission and absorption.Comment: 9 pages, 2 figurs, Phys. Rev. A, Rapid Communication (submitted

A. H. Gabriel

A. K. Pradhan

Anil K. Pradhan

D. G. Hummer

E. Silver

F. Bely-Dubau

H. L. Zhang

Hong Lin Zhang

K. A. Berrington

K. Sakimoto

L. A. Vainshtein

L. Spitzer, Jr.

M. J. Seaton

P. Beiersdorfer

S. Mannervik

S. N. Nahar

Sultana N. Nahar

U. Fano

English

arXiv

Relevant data is available at: http://www.astronomy.ohio-state.edu/~nahar/nahar_radiativeatomicdata/index.htmlRecently x-ray photoabsorption in KLL resonances of O VI was predicted [A. K. Pradhan, Astrophys. J. Lett. 545, L165 (2000)], and detected by the Chandra X-Xay Observatory [J. C. Lee et al., Astrophys. J. Lett. (to be published)]. The required resonance oscillator strengths ƒ¯_r are evaluated in terms of the differential oscillator strength df/dε that relates bound and continuum absorption. We present the ƒ¯_r values from radiatively damped and undamped photoionization cross sections for Li-like C, O, and Fe calculated using relativistic close-coupling Breit-Pauli R-matrix method. The KLL resonances of interest here are 1s2p(^3 P°)2s [^4 P°_1/2,3/2, ^2 P°_1/2,3/2] and 1s2p(^1 P°)2s [^2 P°_1/2,3/2]. The KLL photoabsorption resonances in Fe XXIV are fully resolved up to natural autoionization profiles. It is demonstrated that the undamped ƒ¯_r
independently yield the resonance radiative decay rates, and thereby provide a precise check on the resolution of photoionization calculations in general. The predicted photoabsorption features should be detectable by the x-ray space observatories and enable column densities in highly ionized astrophysical plasmas to be determined from the calculated ƒ¯_r . The dielectronic satellites may appear as redward broadening of resonance lines
in emission and absorption.This work was partially supported by the National Science Foundation and the NASA Astrophysical Theory Program

Nahar, Sultana Nurun

Pradhan, Anil K.

Zhang, Hong Lin

KnowledgeBank at OSU

RAPID COMMUNICATIONSPHYSICAL REVIEW A, VOLUME 63, 060701~R!K-shell dielectronic resonances in photoabsorption: Differential oscillator strengths for Li-likeC IV, O VI, and Fe XXIVSultana N. Nahar and Anil K. PradhanDepartment of Astronomy, The Ohio State University, Columbus, Ohio 43210Hong Lin ZhangApplied Theoretical and Computational Physics Division, Los Alamos National Laboratory, Los Alamos, New Mexico 87544~Received 6 February 2001; published 4 May 2001!Recently x-ray photoabsorption in KLL resonances of O VI was predicted @A. K. Pradhan, Astrophys. J. Lett.545, L165 ~2000!#, and detected by the Chandra X-Xay Observatory @J. C. Lee et al., Astrophys. J. Lett. ~to bepublished!#. The required resonance oscillator strengths f¯r are evaluated in terms of the differential oscillatorstrength d f /de that relates bound and continuum absorption. We present the f¯r values from radiativelydamped and undamped photoionization cross sections for Li-like C, O, and Fe calculated using relativisticthe close-coupling Breit-Pauli R-matrix method. The KLL resonances of interest here are1s2p(3Po)2s @4P1/2,3/2o ,2P1/2,3/2o # and 1s2p(1Po)2s @2P1/2,3/2o # . The KLL photoabsorption resonances inFe XXIV are fully resolved up to natural autoionization profiles. It is demonstrated that the undamped f¯rindependently yield the resonance radiative decay rates, and thereby provide a precise check on the resolutionof photoionization calculations in general. The predicted photoabsorption features should be detectable by thex-ray space observatories and enable column densities in highly ionized astrophysical plasmas to be deter-mined from the calculated f¯r . The dielectronic satellites may appear as redward broadening of resonance linesin emission and absorption.DOI: 10.1103/PhysRevA.63.060701 PACS number~s!: 34.80.Kw, 32.80.Dz, 32.80.FbResonance spectroscopy may be employed to determineelement abundances and ionization structure in astrophysicalsources @1,2#. K-shell line spectra are powerful diagnostictools in x-ray spectroscopy for density, temperature, ioniza-tion state, and abundance laboratory and astrophysical plas-mas ~e.g., @3,4#!. K-shell emission spectra from severalatomic species have been measured in electron-beam-ion-trap experiments @3,5#. Recently it was suggested that, analo-gous to the dielectronic satellite spectra of He-like ions inemission, K-shell x-ray photoabsorption should be detectablein KLL resonances of Li-like O VI @1#. Soon thereafter, theChandra X-Ray Observatory ~CXO! made the first detectionof the strongest of the predicted O VI KLL features at 22.05Å from the so-called ‘‘warm absorber’’ region of ionized gasaround the central source in active galactic nuclei, thought tobe a massive black hole @2#. The observation of x-ray absorp-tion from Li-like O VI in the same wavelength region as theemission lines of He-like O VII enabled the simultaneous de-termination of column densities and, since the two ions donot usually coexist in a plasma, this indicated a compositeplasma with widely disparate temperature regimes @1,2#.Present theoretical calculations for the resonance oscilla-tor strengths employ highly resolved relativistic photoioniza-tion cross sections with fine structure @6,1#. The quantity ofinterest is the differential oscillator strength d f /de that quan-titatively relates photoabsorption per unit energy in thebound-bound and the continuum region as @7–9#d fde 55n32z2f line , e,I14p2aa02 sPI , e.I ,~1!1050-2947/2001/63~6!/060701~4!/$20.00 63 0607where f line is the line absorption oscillator strength, sPI thephotoionization cross section, I the ionization potential, z theion charge, n the effective quantum number at e52z2/n2 inrydbergs, and a and a0 are the fine structure constant and theBohr radius, respectively. In the bound-free region, with au-toionizing resonances, the integrated d f /de yields the effec-tive photoabsorption in terms of sPI , i.e.,f¯r~Ji→J f !5EDErS d f ~Ji→J f !de D de5S 14p2aa02D E sPI~e;Ji→J f !de , ~2!where Ji ,J f are total angular momenta of the initial boundlevel and the final bound or continuum wave function, gov-erned by the usual dipole selection rules DJ50,61;p→2p . Equation ~2! may be evaluated from the detailed sPI forthe Jp symmetries concerned. However, the resonance pro-file needs to be sufficiently well delineated and elaboratemethods need to be employed to obtain accurate positionsand profiles ~the background and the peaks! of resonances.Relativistic effects are essential in order to differentiate thefine-structure components. We employ the coupled-channelformulation based on the relativistic Breit-Pauli R-matrix~BPRM! method employed on the extensive work on the IronProject @10–12#.BPRM photoionization and recombination calculationswere reported in earlier works for Li-, He-, H-like carbon,and iron: C IV, C V, C VI @13,14# and Fe XXIV, Fe XXV,Fe XXVI @15,16# for applications to x-ray photoionizationand non-LTE ~NLTE! modeling. We consider the photo-ionization of the ground level of the Li-like ions C IV, O VI,©2001 The American Physical Society01-1RAPID COMMUNICATIONSNAHAR, PRADHAN, AND ZHANG PHYSICAL REVIEW A 63 060701~R!TABLE I. X-ray wavelengths and KLL photoabsorption resonance oscillator strengths for C IV, O VI, and Fe XXIV. Notation a@6b#means a3106b. The NRD and RD values refer to without and with radiation damping. Ga and Gr are the autoionization and radiative decayrates, respectively.Resonance lcal Er f¯r Ga Gr~Å! ~KeV! NRD ~RD! ~Ry, s21) ~Ry, s21)C IV1s2p(1Po)2s 2P1/2o ~r! 41.42 0.2993 0.3402 ~0.3148! 3.24@-4#, 6.70@12# 2.97@-5#, 6.13@11#1s2p(1Po)2s 2P3/2o ~u! 41.42 0.2993 0.1694 ~0.1571! 3.18@-4#, 6.58@12# 2.93@-5#, 6.05@11#1s2p(3Po)2s 2P1/2o ~t! 40.94 0.3028 0.0342 ~0.0342! 2.75@-3#, 5.69@13# 3.47@-6#, 7.16@10#1s2p(3Po)2s 2P3/2o ~s! 40.94 0.3028 0.0177 ~0.0177! 2.75@-3#, 5.69@13# 3.34@-6#, 6.91@10#O VI1s2p(1Po)2s 2P1/2o ~r! 22.05 0.5623 0.1924 ~0.141! 3.11@-4#, 6.42@12# 1.26@-4#, 2.60@12#1s2p(3Po)2s 4P3/2o ~u! 22.05 0.5623 0.3837 ~0.267! 2.76@-4#, 5.70@12# 1.28@-4#, 2.65@12#1s2p(3Po)2s 2P1/2o ~t! 21.87 0.5670 0.0217 ~0.0216! 3.41@-3#, 7.11@13# 1.46@-5#, 3.01@11#1s2p(3Po)2s 2P3/2o ~s! 21.87 0.5670 0.0391 ~0.0390! 3.43@-3#, 7.09@13# 1.32@-5#, 2.72@11#Fe XXIV1s2p(1Po)2s 2P1/2o (v) 1.873 6.617 2.05@-3# ~1.61@-4#! 7.48@-6#, 1.54@11# 1.77@-4#, 3.66@12#1s2p(1Po)2s 2P3/2o ~u! 1.870 6.627 1.42@-2# ~7.63@-4#! 3.12@-5#, 6.45@11# 6.38@-4#, 1.32@13#1s2p(1Po)2s 2P1/2o ~r! 1.864 6.649 1.46@-1# ~1.77@-2#! 1.89@-3#, 3.90@13# 1.35@-2#, 2.80@14#1s2p(3Po)2s 4P3/2o ~q! 1.860 6.663 4.91@-1# ~2.58@-4#! 8.98@-6#, 1.86@11# 2.29@-2#, 4.74@14#1s2p(3Po)2s 2P1/2o ~t! 1.857 6.674 1.10@-1# ~2.66@-2#! 3.43@-3#, 7.10@13# 1.04@-2#, 2.14@14#1s2p(3Po)2s 2P3/2o ~s! 1.855 6.681 6.56@-3# ~6.24@-3#! 5.12@-3#, 1.06@14# 2.82@-4#, 5.83@12#and Fe XXIV, 1s22s (2S1/2) into all n51,2,3 fine-structurelevels of the He-like ion with 1s2(1S0), 1s2s(3S1 ,1S0),1s2p(3P0,1,2o ,1P1o), 1s3s(3S1 ,1S0), 1s3p(3P0,1,2o ,1P1o),and 1s3d(3D1,2,3 ,1D2) in the close-coupling expan-sion. Thus K-shell photoionization of the (1s22s), i.e.,inner-shell excitation autoionization via the 1s→2p transi-tion resulting in 1s2s2p (KLL) resonances, is con-sidered with the initial bound state (2S1/2) with symmetryJ50.5 ~even parity!, and final continua with J50.5 and1.5 ~odd parity!. The six KLL resonances ofinterest here are 1s2p(3Po)2s @4P1/2,3/2o ,2P1/2,3/2o # and1s2p(1Po)2s @2P1/2,3/2o # ~the resonances are labeled in TableI according to the alphabetical notation by Gabriel @17#!. Theautoionization and radiative decay rates and cross sections,with and without radiative decay of resonances back to theground level, are calculated by analyzing the poles in thecomplex dipole matrix elements using the method describedin @16,18#. The cross sections are resolved on a very fineenergy mesh of up to 1026 eV.Whereas calculations have been carried out for C IV, O VI,and Fe XXIV, for brevity we present only the detailed photo-ionization cross section of the Fe XXIV ground state in Fig. 1from the L-shell (2s) ionization threshold at Fe XXV(1s2 1S0), up to the K-shell ionization thresholds at 1s2s and1s2p ~marked by arrows in the figure!. The top panel ~a!presents the sPI over the extended range with the KLnn>2 complexes of resonances KLL , KLM , KLN , etc. ~atcomputed wavelengths! converging on to the K-shell ioniza-tion edges. The bottom panel ~b! shows the region of KLLresonance complex on an expanded scale, and the strongestresonance ~labeled ‘‘q,’’ Table I!, fully delineated in ~c!,showing the orders-of-magnitude effect of radiation damp-06070ing. The calculations are further subdivided into the constitu-ent total Jp symmetries for the (e1ion) continua, and wethereby fully resolve the lowest KLL resonance complexinto the six distinct resonance features allowed by the orbitaland spin-angular-momentum couplings, as shown in the bot-tom panel of Fig. 1. Two sets of cross sections arecomputed—with and without radiation damping of reso-nances ~solid and dashed lines, respectively!. It is noted thatthe Y scale ~megabarns! in the upper panel is linear, whereasin the bottom panel it is log10 , i.e., the resonance peaks riseorders of magnitude above the nonresonant background. Fur-ther, the radiative damping effect attenuates the peak reso-nance strengths by similarly large amounts, but it is differentfor each resonance.These resonances have heretofore been observed in thelaboratory as dielectronic satellites ~DES! formed viaelectron-ion excitation of the core ion followed by dielec-tronic recombination ~DR!, i.e., radiation damping of thecore of the doubly excited autoionization state ~e.g., Li-likeC IV @4#!. We may distinguish the DR resonances DES, fromthe ‘‘photoabsorption resonances’’ ~PAR! ase11s2→1s2s2p→1s22s1hn~DES!,hn11s22s→1s2s2p~PAR!. ~3!The PAR’s therefore manifest themselves in photoioniza-tion cross sections and photoabsorption spectra, whereas theDES appear in the emission spectra. For lighter elementssuch as C and O, the PAR’s are not likely to be also ob-served as DES. Thus, in general, resonances may be dividedinto PAR or DES according to their actual formation andobservation depending on plasma conditions in the source.1-2RAPID COMMUNICATIONSK-SHELL DIELECTRONIC RESONANCES IN . . . PHYSICAL REVIEW A 63 060701~R!FIG. 1. Ground-state photo-ionization cross section of Fe XXIVwith the K complex of resonances~a!, the resolved KLL resonances~b!, and completely resolved pro-file of the q resonance ~c!. Notethe different energy scales on thex axis in ~a!, and in ~b! and ~c!.The upper panel has a linear Yscale ~Megabarns!, but the lowerpanel is on a log10 scale, indicat-ing the height of resonances. Thelarge radiation damping of the ‘‘q’’ resonance ~c! is related to itslarge f¯r , stronger than all otherresonances ~solid line, damped;dashed line, undamped!.For example, in ions of heavier elements such as Fe XXIV, weexpect the same set of resonances to act as PAR’s or theDES, and provide useful plasma diagnostics—absorptionfrom a cold or cooling environment ~with Li-like Fe XXIV,for example!, or emission at higher temperatures ~with DRfrom He-like Fe XXV!. Since both the DES and the PAR aresatellite features on the long-wavelength side of the reso-nance lines, they should appear as ‘‘redward broadening’’ ofthe primary resonance transitions in emission or absorptionspectra. This fact may be of considerable astrophysical sig-nificance in the analysis of x-ray spectra, where such asym-metric broadening of resonance lines is observed, and issometimes ascribed to relativistic gravitational broadeningdue to the proximity of the plasma source to a massive blackhole ~see the discussion in Ref. @2#!.Table I gives the computed resonance parameters: the as-sociated autoionization and radiative rates (Ga ,Gr), as wellas the radiatively undamped ~NRD! and the damped ~RD! f¯rfor the KLL resonances in C IV, O VI, and Fe XXIV. The f¯r~NRD! are the conventional f-values, but computed for reso-nances; the f¯r ~RD! are further multiplied by the ratio of theradiative rate back to the ground level and the sum of allradiative rates. The f¯r ~C IV,NRD! agree well with the lengthf values computed in @4# to 3.9% for the 1s2p(1Po)2s , andto 0.9% for the 1s2p(3Po)2s resonances.The ‘‘q’’ resonance in Fe XXIV @Fig. 1~c!# is the narrowestone with an extremely small Ga , the lowest among the KLLPAR’s. But it has the largest Gr , and hence the largest reso-nances oscillator strength f¯r , resulting in the most dampedprofile. In previous works the resonances Ga ,Gr are gener-ally determined either in the isolated resonance approxima-tion ~e.g., @19,20#!, or through fitting of complex dipole ma-trix elements for the dielectronic satellite resonances ~e.g.,06070@18,13,16#!. The resonances themselves are not fully re-solved up to their natural autoionization widths. In thepresent work, the q resonance required an order-of-magnitude finer resolution than that needed to derive Ga ,Grfrom fitting alone ~given in Table I!. The f¯r obtained fromintegration over completely resolved d f /de accounting forall the oscillator strength ~as for Fe XXIV! should be some-what more accurate than from the fits or isolated resonanceapproximation when interference between the backgroundand the resonant parts of the wave functions is significant.The f¯r in Table I agree very well with those derived from fitsto resonances @16#. Another independent check is that thesum over the f¯r for the KLL resonances of Fe XXIV, 0.782,agrees well with the total absorption oscillator strength in theE1 dipole-allowed and intercombination transitions in thecore ion Fe XXV f (1s2 1S021s2p (3,1)P1o), 0.772.The present calculations therefore enable not only the cal-culation of PAR oscillator strengths, but also provide themost stringent check on the accuracy of photoionization cal-culations. For C IV and O VI all six KLL resonances are notfully delineated due to overlapping and weak components,but the stronger components account for nearly all the ex-pected oscillator strength; the weak components have verysmall Ga and small f¯r . We should expect the KLL reso-nances in C IV and O VI to manifest themselves only asPAR’s, and not DES, since the radiative rates are small com-pared to autoionization rates.The computed d f /de for the three ions are shown in Fig.2, extending from the bound-bound region with the (2s2np) transitions to the bound-free (2s2ep) in the x-rayregion. It may be noted that the bound-bound region is in theUV for C IV and O VI, but in the x ray for Fe XXIV with theexception of the n52 transition in the extreme UV. The1-3RAPID COMMUNICATIONSNAHAR, PRADHAN, AND ZHANG PHYSICAL REVIEW A 63 060701~R!bound-bound oscillator strengths are computed up to n510from the same eigenfunction expansion as in the photoion-ization and recombination work in Refs. @14,15#; all atomicparameters are thereby obtained in a theoretically self-consistent manner. The Fe XXIV and Fe XXV oscillatorstrengths were reported in Ref. @21# ~those for carbon andoxygen ions are as yet unpublished but may be obtainedFIG. 2. Differential oscillator strengths d f /de for C IV, O VI,and Fe XXIV. Wavelengths of the main line and resonance featuresare marked. The PAR f¯r ’s in Table I give the expected strengths inx-ray-absorption spectra.@@@06070from the first author!. The d f /de are continuous across theionization threshold, but reflect magnitudes and the struc-tures of discrete and resonant transitions.1 In the bound-bound region the d f /de (2s2np) is much smaller for n52 than for n53, owing to the respective energy differ-ences. The d f /de therefore rises from n52 to 3, and thendecreases monotonically towards higher n and the first ion-ization threshold as n→‘ (e→0). Figure 2 presents a com-plete picture of photoabsorption from the Li-like C IV, O VI,and Fe XXIV, from L-shell absorption to the KLL x-ray fea-tures, which should provide plasma diagnostics in two quitedifferent wavelength ranges from the same ionic species.The wavelengths shown in Fig. 2, together with the f¯r inTable I, mark the positions and strengths of discrete photo-absorption in the x ray by Li-like C, O, and Fe. The predictedfeatures and the calculated resonance oscillator strengths f¯rshould be useful in the interpretation of x-ray spectra fromthe CXO and the X-Ray Multi-Mirror Mission, and determi-nation of column densities using the standard curve-of-growth method @22#. Further, the significant differences be-tween f¯r ~NRD! and f¯r ~RD!, without and with radiativedamping, may indicate optical depth effects in the plasma; f¯r~NRD! is the value to be used in optically thin cases wherereemission following photoabsorption in the resonance alongthe line of sight is unlikely. More generally, this work dem-onstrates that resonance photoabsorption spectroscopy canprovide information complementary to line emission spec-troscopy, and should prove to be a powerful tool for plasmadiagnostics, such as for ionization fractions and abundancesof elements in astrophysical and laboratory plasmas.This work was partially supported by the National Sci-ence Foundation and the NASA Astrophysical Theory Pro-gram. The computational work was carried out at the OhioSupercomputer Center.1Owing to a typographical error in the plotting routine,d f /de~O VI,n52)50.02115 is incorrectly shown in Fig. 2 of Ref.@1# as 0.2115.@1# A. K. Pradhan, Astrophys. J. Lett. 545, L165 ~2000!.@2# J. C. Lee et al., Astrophys. J. Lett. ~to be published!; e-printastro-ph/0101065.@3# E. Silver et al., Astrophys. J. 541, 495 ~2000!.@4# S. Mannervik et al., Phys. Rev. A 55, 1810 ~1997!.@5# P. Beiersdorfer et al., Phys. Rev. A 46, 3812 ~1992!.@6# H. L. Zhang and A. K. Pradhan, Phys. Rev. Lett. 78, 195~1997!.@7# M. J. Seaton, Rep. Prog. Phys. 46, 167 ~1983!.@8# U. Fano and A. R. P. Rau, Atomic Collisions and Spectra~Academic Press, San Diego, 1986!.@9# A. K. Pradhan and H. E. Saraph, J. Phys. B 10, 3365 ~1977!.10# D. G. Hummer et al., Astron. Astrophys. 279, 298 ~1993!.11# K. A. Berrington et al., Comput. Phys. Commun. 92, 290~1995!.12# Information on the Iron Project and publications is at the fol-lowing homepages: www.usm.uni-muenchen.de/people/ip/iron-project.html and www.astronomy.ohio-state.edu/;pradhan@13# H. L. Zhang et al., J. Phys. B 32, 1459 ~1999!.@14# S. N. Nahar et al., Astrophys. J., Suppl. 131, 375 ~2000!.@15# S. N. Nahar et al., Astrophys. J., Suppl. 133, 255 ~2001!.@16# A. K. Pradhan and H. L. Zhang, J. Phys. B 30, L571 ~1997!.@17# A. H. Gabriel, Mon. Not. R. Astron. Soc. 160, 99 ~1972!.@18# K. Sakimoto et al., Phys. Rev. A 42, 291 ~1990!.@19# L. A. Vainshtein and U. I. Safronova, At. Data Nucl. DataTables 25, 49 ~1978!.@20# F. Bely-Dubau et al., Mon. Not. R. Astron. Soc. 198, 239~1982!.@21# S. N. Nahar and A. K. Pradhan, Astron. Astrophys., Suppl.Ser. 135, 347 ~1999!.@22# L. Spitzer, Jr., Physical Processes in the Interstellar Medium~Wiley, New York, 1978!.1-4

Physical Review A

K-shell dielectronic resonances in photoabsorption: Differential oscillator strengths for Li-like C IV, O VI, and Fe XXIV

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K-shell dielectronic resonances in photoabsorption: differential
  oscillator strengths for Li-like C IV, O VI, and Fe XXIV

K-shell dielectronic resonances in photoabsorption: differential oscillator strengths for Li-like C IV, O VI, and Fe XXIV

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