Ionization of Hydrogenic 3d State by Electron Impact

The triple differential cross sections estimation have been ascertained theoretically for the ionization of metastable 3d-state hydrogen atoms by electron at 150 eV, 200 eV and 250 eV for assorted kinematic conditions exerting a multiplex scattering principle. The existent new-findings are assimilated with the theoretic data of hydrogenic metastable 2S, 3S and 3P states as well as the hydrogenic ground state experiment. An analysis of the attained observations reveals qualitative fitness with those of compared results specially with hydrogenic ground state BBK model, ground state experimental data and metastable state 2S state results. This is a new theoretical work on hydrogenic metastable 3d state ionization by electron. The substantial progress of the current study offers a wide scope for empirical study in ionization process.


Introduction
In high energy ion-atom collisions, ionization is one of the most momentous reactions. Electron impact ionization by charged particles is used in solving problems in isolated range of field like astrophysics, plasma physics, fusion technology, radiation physics, etc. The triple differential cross-sections have been attained in ejected electron energy and ejected angles in the electron hydrogen mechanism. The major challenge in the field of electron impact ionization is to develop a general theoretical framework, which will provide an accurate ionization cross sections for many atoms over a relevant impact energy range. Due to its perplexity, the fully quantum mechanical conduct of atomic ionization by electron is possible for the artless cases of hydrogen atom. In this work, atomic hydrogen is used as target in order to focus attention on the colli-sion mechanism and to investigate the range of validity of various theoretical models.
Ionization by fast particle was first initiated quantum mechanically by Bethe [1]. Electron atom ionization collision on different cross sections has become gradually interesting over the last four decades both theoretically and experimentally for non-relativistic [2]- [21] as well as relativistic [22]- [25] energies.
Various theoretical models applying different kinematical conditions have been vastly used for experimental measurements. Ehrhardt et al. [3] have investigated this more successfully for different energies of the incident electrons from very low to high energies. The present new theoretical study on hydrogenic 3d state ionization by electron offers an immense opportunity for further experimental study for ionization of hydrogenic metastable 3d state by electron.
Ionization of the hydrogenenic atom by electron is a good image for perturbation theory because of the existence of empirical consequence. In this text, the electron-electron coincidence experiments called (e, 2e) experiments which offer a translucent idea of the kinematics of the collisions by delivering knowledge about the direction of the scattered and ejected electrons. The quantity measured in this kind of experiment is proportional to the TDCS, which represents the angular distribution of the ejected electron for selected incident and scattered electron momenta.
A multiple scattering wave function has been designed for two electrons moving in a coulomb field which include higher order and correlation effects. Lewis integral [26] has been used in the present study for analytic estimation. A multiple scattering principle [5] has been followed in the present study by 150 eV, 200 eV and 250 eV energies. The multiple scattering principle [5] plays a vital role in the study of hydrogenic ionization for ground state [14] and metastable states [15] and [18]- [21]. So, the present results seem to be interesting. The existent novel theoretical results make a new dimension on ionization of hydrogenic metastable states. Current results are compared with previous related theories [15], [19], [20].

Theory
T-matrix element for ionization of hydrogen atoms by electrons pursuing Das and Seal [5] may be taken as Here, 1 r and r represent the coordinates of the atomic active electron and the incident electron, ( 1 p , 2 p ) and ( 1 E , 2 E ) represent the momenta and energies of the two electrons in the final state and ( i p , i E ) are the momentum and the energy of the incident electron.
Where the perturbation potential ( ) 1 2 , i V r r is given by ( ) The nuclear charge of the hydrogen atom is Z = 1, 1 r and 2 r are the distance of the two electrons from the nucleus and 12 r is the distance between two electrons.
The initial channel unperturbed wave function is given in the following form ( ) ( ) ( ) is approximate wave function is given by [5] The normalization constant ( ) 1 2 , N p p is calculated using Das and Seal [5] and Dhar and Nahar [18].
The Coulomb wave function is used from Das and Seal [5] and Dhar and Nahar [18].
The triple differential cross-sections for direct T-Matrix element is given by Here the direct scattering amplitude ( ) 1 2 , f p p is computed in [21].
The exchange scattering amplitude ( ) TDCS with exchange effects is given by Right hand side of Equation (3) is computed numerically by exerting computer programming language Mat-Lab.

Results and Discussions
Ionization of hydrogenic metastable 3d state by electron impact is presented for  [10], [13] and the absolute data [3].
The ionization results of hydrogenic metastable 2S state [15], 3S state [19] and 3P state [20] are also covered here for comparison with our new theoretical study results. In this text, the ejected angle 1 θ varies from 0˚ to 360˚ where In Figure 1(a) peak values of present first Born black dash curve, direct black  where it is expected.
In Figure 1(b), current first Born result show flat peak magnitude and direct results show minimum peak magnitude than the hydrogenic ground state experimental results [3], hydrogenic ground state BBK model [10] and present exchange result. In the recoil field, present exchange results show uniquely closer with low magnitude to the hydrogenic ground state experimental result [3] but in the binary field, present direct and exchange outcomes are moved forward direction from the compared results [3], [10].
In Figure 1(c), Existence first Born result is assembled with hydrogenic ground state experimental result [3], BBK result [10] and current direct result.
The peak pattern of present direct and exchange results provide similar but shifted onward direction from hydrogenic ground state second Born results [13].
Peak magnitude of existence exchange results which is upper than other compared results [3], [10] in both recoil and binary field.
In Figure 2(a), in the recoil field, about 1 60 θ = , present first Born results make a petty peak and on the other side, current direct configuration make a short lobe with 3S-state results [20] and current exchange result. In the binary field, the magnitude of obtained exchange outcome is decreased from other compared results [15], [19], [20].
In Figure 2(b), present first Born curve express identical behavior with 3P-state curve [20] and direct curve depict similar conduct with 3S-state curve [20] in the recoil field. The present exchange result is reversely jointed with 3P-state results [20] at higher ejected angle about 1 288 θ = . In Figure 2(c), in the recoil field at approximate 1 60 θ = , existent first Born structure create same peak pattern with 2S-state structure [15] whereas present direct curve conjoined contrarily with 2S-state [15] and existent exchange curve make a nice lobe. New exchange result form minimum peak magnitude than 2S-state result [15] in the binary field.
In Figure 2(d), current attained first Born configuration conjoined with 2S-state [15] and 3S-state [19] configurations in the recoil field near about In Figure 2(e), existent first Born curve provides almost similar behavior with 3S-state [19], 3P-state [20], present direct and exchange curves but shows a gross difference with the results of 2S-state [15] in recoil field at about 1 45 θ = . The existent first Born diagram give same peak with 3P-state [20], present direct and In Figure 2(f), present first born configuration meets contrarily with 3S-state [19] configuration while present direct and present exchange configuration meets reversely with 3P-state [20] configuration in the recoil field at about 1 148 θ = . Present exchange diagram display opposite form with 3P-state [20] diagram in both recoil and binary field. . Theory: Black dash curve, Black continuous curve, Red perfect curve exhibit present first Born, direct and exchange effect results respectively. Also Green dash dotted curve display hydrogenic 3P-state result [20], Magenta dotted curve expose hydrogenic 3S-state result [19] and Blue dash dotted curve demonstrate hydrogenic 2S-state result [15].
To understand these structures, a table (please see Table 1) which is given for assimilation of hydrogenic ionization of 3d state with 2S-state, 3S-state, 3P-state results.
In Figure 3   Here a table (please see Table 2) which is presented for assimilation of first Born, direct and exchange results of hydrogenic 3d-state ionization.
In Figure 4

Conclusion
The present calculation exposes additional possible structure of the cross-section curves for intermediate momentum transfer in the hydrogenic 3d-state ionization at 150 eV, 200 eV and 250 eV impact energy. In the present estimation, the correlated three particle final state wave function of Das and Seal [5] has been followed. New theoretical computational observations for ionization of hydrogenic 3d state by electrons may be generalized for application to the other atom as well as ions and which may play a vital role to provide much interesting and potential results in this field of research.