Abstract

The nonresonant cross-section, Fano-shape parameter and coefficient parameter have been calculated for the photoionization of helium and heliumlike under the threshold of the residual ions. Dipole matrix elements which correspond to the transitions from to state and from state to continuum state 1sp () were determined by choosing, for the ground state, the six-parameter Hylleraas wave function including electron correlation effects and a completely screened Coulomb wave function for the continuum. Energies and widths have been determined in the diagonalization method. The results are compared with available results obtained by other theoretical approaches.

1. Introduction

Doubly excited states of helium were first studied experimentally in the pioneering work of Madden and Codling [1] with the availability of synchrotron radiation. Madden and Codling [1] observed the two series of transitions converging to the He+ () ionization limit, using a photoabsorption technique. Thereafter, many experimental studies [28] were carried out on the doubly excited states of helium, and much effort has been done in photoionization that leaves the He+ ion in an excited state. Single-photon double-excitation experiments of Domke et al. [911] using synchrotron radiation combined with high-resolution monochromators, and even further improved monochromators in the experiment of Schulz et al. [12] made it possible to reveal for the first time several additional Rydberg series. Domke et al. [9] resolved for the first time the third Rydberg series, , below the ionization threshold. Theoretically, various methods were developed to deal with doubly excited states of helium, including configuration-interaction (CI) methods [1315], hyperspherical coordinate methods [1623], close-coupling approximations [2426], R-matrix methods [2732], complex coordinate method [3336], Feshbach projection formalism [3740], and the diagonalization method [4147]. A detailed review was recently performed by Tanner et al. [48].

Since the identification of doubly excited states of He by Madden and Codling [1], it has been well established that these states cannot be adequately described in the conventional independent-particle model. According to the conventional model, the two electrons are described by using quantum numbers , , , , , and , within the coupling, with , the principal quantum number of electron . Because of the strong configuration, these quantum numbers are not sufficient to identify the states. A different classification scheme for doubly excited states of He is used depending on authors. In the classification introduced by Moccia and Spizzo [13] and Lin [18], states are denoted by where , , and have their usual meaning, and are the principal quantum numbers of the inner and outer electrons, respectively, and , , and are correlation quantum numbers. ranges from –1–, –3––(–1–), and or 1 for states. Both and describe the angular correlation between the two electrons, while  or denoted by “+”, “−”, “0” measures the radial correlation [18]. The doubly excited states-basis (DESB) functions proposed by Moccia and Spizzo [13] represent the first-order approximation of these states. Through the analysis of electron correlations, a new set of quantum numbers were introduced to replace the quantum numbers used in the independent particle model. There is also an abbreviated classification , as introduced by Zubek et al. [6]. There are three series converging to the threshold: 2, with and with and , and with and . These sates correspond respectively to (), (), and () in the old classification scheme.

Until recently, doubly excited states lying the received great attention. In their work, Yuan et al. [49] reported Fano profile parameters of doubly excited states ,, and as functions of the momentum transfer squared . Fan and Leung [50], presented a detailed characterization of the absolute generalized oscillator strength (GOS) profile of the He transition by using electron energy loss spectroscopy (EELS) at 2.5 keV impact energy, and they illustrated the intricate changes in the Fano parameters as functions of the momentum transfer. Prince et al. [51] measured the photoabsorption cross-section and ion-yield spectra of He in the region of the double-excitation resonances below the threshold. Very recently, more than thirty years after the experimental work of Carroll and Kennedy [52], Scully et al. [53] measured the absolute cross-section for resonant double photoexcitation of Li+ followed by autoionization in the photon energy range from 148 eV, just below the resonance to 198 eV.

In this present work, we focused on the determination of Fano-Shape parameter or profile index , correlation coefficient , and nonresonant cross-section in the photoionization of helium and heliumlike with charge , and 10 from the ground state to the state. Until now, only few theories have calculated and for helium and heliumlike Li+ and C4+, and in addition, experiments on the photoionization of heliumlike positive ions are very scarce. Here we extend calculations to heliumlike N5+, O6+, and Ne8+. We also present energies and widths, calculated in the diagonalization method, which we have already used in our previous works [4347].

2. Theory and Calculations

In Fano’s theory [58], describing photoabsorption in the vicinity of an autoionizing resonance, which coincides in energy with a continuum, Fano profile consists of a constructive and a destructive interaction of the direct photoionization with the indirect photoionization via doubly excited or autoionizing states. So, according to Fano, the total Cross-Section for the case of an isolated resonance interacting with one or more continuum states can be parameterized as follows: where is the resonance energy, the width, indicates the deviation of the incident photon energy from the resonance energy , and represent the Cross-Section corresponding, respectively, to transitions to states of the continuum that do and do not interact with the discrete autoionizing state and finally which characterizes the line profile representing the ratio of the dipole matrix element of a transition to a discrete state to that of a transition to the continuum, which interacts with the discrete state. In the present case, the Rydberg series converging to the threshold interact with the continuum above the ionization threshold. In this theory [58], the profile index can vary from , when the transition probability into the discrete state is dominant (Lorentzian profile), to , when the transition probability into the discrete state is much smaller than that into the continuum, leading to a symmetric decrease of the Cross-Section to a minimum value (‘‘window’’ resonance). Fano and Cooper [59] express the total Cross-Section in terms of the nonresonant Cross-Section and the profile index and correlation coefficient as follows: where is a measure of the strength of the resonance.

In the diagonalization approximation, the final state of the ion + photoelectron system is expanded in the subspaces of closed and open channels as follows: where is the operator of antisymmetrisation, represents a set of quantum numbers that characterize the ion + photoelectron system in the subspace of open channels; is an unknown function describing the motion of the photoelectron and is the eigenfunction of the residual ion.

The determination of the function is equivalent to the calculation of the coefficients and . Detailed calculations of these coefficients have been reported by [41, 42].  The functions are obtained by unitary transformation of the Hamiltonian in the subspace of closed channels which are the autoionizing states: With the diagonalization condition: is the Hamiltonian operator; the coefficients which are the statistical weight of the autoionizing states are found by solving the system of linear algebraic equations: where is the energy of the autoionizing level ; is the operator of electrostatic interaction between electrons; is the energy eigenvalue of the zero-order Hamiltonian corresponding to the eigenfunctions defined by: The partial amplitude that describes the formation of the residual ion and photoelectron in a definite state has been defined by the following expression: In (8), is the initial state and is the wave function of the continuous spectrum in the channel , without resonance interference; is the dipole momentum operator; is the profile index of the resonance and , the relative deviation from the resonance, are defined by the equations: With the total width:

In the diagonalization approximation, the total Cross-Section defined by Fano [58] can be expressed with the total amplitude by With and representing the Cross-Section corresponding, respectively, to transitions to states of the continuum that do and do not interact with the discrete autoionizing state and defined as follows: The nonresonant Cross-Section is thus defined by: The coefficient correlation can be expressed by:

In the present work, we consider for the ground state, the six-parameter Hylleraas wave function including electron correlation effects, and as the emitted electron is in the field of the residual hydrogenic ion, the continuum is represented by a completely screened Coulomb wave function. Energies of resonant states are determined in the framework of diagonalization approximation which has been detailed and discussed earlier [4147]. Particular interest of the diagonalization method is to take into account the coupling between closed and open channels in terms of perturbation theory and to neglect the indirect coupling of resonant states through the open channels. The determination of Cross-Section, , and coefficient parameter is carried out by calculating the dipole matrix elements which correspond to the transitions from () to state and from state to continuum state .

3. Results and Discussion

In Table 1, present results on helium are compared with the experimental works of Madden and Codling [1], Schulz et al. [12], Kossmann et al. [5], and Domke et al. [11]. Present results are in good agreement with these experiments. Our profile index is close to the experimental result of Madden and Codling [1] and is in good agreement with the other experimental values. Energies and widths presented are also in good agreement. For the nonresonant Cross-Section, our result is close to the only available one, the value of Kossmann et al. [5].

Concerning the coefficient correlation, the value (close to unit) we have found is in very good agreement with the experimental ones and agrees with the fact that when there is only one open channel, the part of the Cross-Section corresponding to transitions to states of the continuum that do not interact with the discrete autoionizing state is negligible compared to . This value agreed with the value assumed by the work of Fano and Cooper [59] for a Rydberg series interacting with one continuum. In Table 2, comparison is made with theoretical results of Altick and Moore [54] using configuration interaction method, Burke and McVicar [55] using the close coupling method, Sanchez and Martin [56] using variational method with basis set, Bhatia and Temkin using Feshbach formalism [38] and a 84-term Hylleraas for the resonant wave functions, Zhou et al. [26] using hyperspherical close-coupling calculations, and Wintgen and Delande [36] using a complex rotation method. Present results are in agreement with all these theoretical works using highly accurate calculations.

In Table 3, present results on Li+ are given along with the theoretical works of Zhou et al. [26], Sanchez and Martin [56], Bhatia and Temkin [38], Diehl et al. [57], and with the experimental works of Carroll and Kennedy [52] and Scully et al. [53]. For index profile, our result is in good agreement with the experimental ones but is greater than the other theoretical works. Discrepancies observed could be explained by the fact that the nonresonant Cross-Section we calculated is greater than those of other theoretical results. The present correlation coefficient is in good agreement with the only available one. Moreover, for better comparison, it would be necessary to get more experimental results.

In Table 4, the comparison of our results on C4+ is made with the only available theoretical work of Zhou et al. [26]. Any experimental work has been reported in the literature. We noticed also the greater values of our profile index and nonresonant Cross-Section. In Table 5, we present our results concerning the N5+, O6+, and Ne8+ Ions without any comparison because of lack of other experimental and theoretical results.

The analysis of the different parameters show that the nonresonant Cross-Section decreases with increasing as found by Zhou et al. [26]. This decreasing is due to the fact that the matrix elements which contain the wave function of the ground state decrease with the electron-electron interaction with increasing . For all considered ions, the correlation coefficient is equal or very close to unity, which is expected from (15) when there is one open channel. For profile index, the behaviour is difficult to explain. It increases with , from −2.86 for He, to −1.5 for Li+, and −1.20 for C4+, thereafter it decreases from −1.22 for N5+ to −1.38 for Ne8+. This disagrees with the analysis of Sanchez and Martin [56] who found a limit of −1.7 by increasing . However, the unique remark is the negative sign of for all ions which agree with the Fano and Cooper [59] analysis. Thus, as already noticed by Morgan and Ederer [3], the profile index is the most parameter to measure and to calculate, larger variation in calculations and experiments is observed.

4. Conclusion

In this work, nonresonant Cross-Section, correlation coefficient and profile index of the photoionization of helium and heliumlike Li+, C4+, N5+, O6+, and Ne8+ under the threshold have been calculated. For helium, a good agreement has been found between our values and the experimental and theoretical values. For Li+, our result for is close to the experimental work, but greater than the other theoretical values as for C4+. The analysis shows that it will be necessary to determine these parameters for all the Rydberg series under the threshold and also for states lying under the upper thresholds when several channels are open for a better understanding of their behaviour. More experimental values are requested for a better understanding of these discrepancies. For the nonresonant Cross-Sections and correlation parameter, quite good agreement was found between present results and those previously obtained with the use of highly accurate calculations.

Acknowledgments

The authors would like to thank the Third world Academy of Sciences (TWAS) and the Abdus Salam International Centre of Theoretical Physics for their financial support. The authors also express our recognition to the late Professor Denardo.