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New Contributions to A+M Databases for Plasma Modeling. R.K. Janev Macedonian Academy of Sciences and Arts, Skopje, Macedonia. IAEA RCM on A+M data for plasma modeling, Nov. 17-19, 2008. Outline:. Electron impact processes: - Excitation of A, B, C, electronic states of CH;
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New Contributions to A+M Databases for Plasma Modeling R.K. Janev Macedonian Academy of Sciences and Arts, Skopje, Macedonia IAEA RCM on A+M data for plasma modeling, Nov. 17-19, 2008
Outline: • Electron impact processes: - Excitation of A, B, C, electronic states of CH; - Dissociative electron attachment on H2(v) in the 14 eV energy region • State-selective electron capture in H(1s) – fully stripped ion collisions • Electron loss cross sections of Liq+ , Beq+ , Bq+ and Cq+ ions colliding with H and H+
e-impact excitation of A2∆,B2Σ-,C2 Σ- states of CH: 0-0 transitions (collaboration with R. Celiberto and D. Reiter) Cross sections: ** E ≤ 10 eV: R-Matrix (Baluja, Msezane, J.Phys.B: 34, 3157 (2001)) ** E ≥ 20 eV: Bethe –Born ** 10 eV ≤ E ≤ 20 eV: interpolation
Basis for Bethe-Born calculations: Potential energy curves, excitation energies, dipole transition moments: X2Π→ A2∆ : Larsson, JCP (1983) X2Π→ B2Σ-,C2 Σ- : Dishoeck, JCP (1986)
v-v’ transitions: scaling σX,Fv,v’ (x) ~ (1/x )(1/∆EX,Fv,v’) MX,Fv,v’ (Born) x = E/∆EX,Fv,v’ , MX,Fv,v’ = |<v’|D(R )|v>|2 σX,Fv,v’ =(∆E0,0’/∆Ev,v’ )X,F (Mv,v’ / M0,0’)X,FσX,F0,0’ (x) F = A, B, C
Dissociative electron attachment on H2(v) near 14 eV (collaboration with R. Celiberto, J. Wadehra and A. Laricchiuta) e + H2(X;v)→ H2−(2Σg+) → H−(1s2) + H(2s) ** Feshbach resonance with a, c triplets and C, EF singlets as parent states; ** Er(R)and Γ(R) determined by Stibbe, Tennyson (J.Phys.B, 1998) for R ≤ 4a0
Method: • Resonace theory with local complex potential; • Exrapolation of S&T data for R ≥ 4a0; • RVE calculations with this extrapolation gave good agreement with Gomer and Read exp. data
State-selective electron capture in H(1s) - AZ+ and He2+ -He+ collisions (collaboration with J.G. Wang and L. Liu, Beijing) • AZ+ = H+, He2+ , C6+ , O8+ • He+ = He+(1s), He+(2s) • Method: AOCC with extremely large expansion basis (the largest to date)
Close-coupling equations Initial conditions Cross sections for excitation, capture and ionization
Used AO basis sets • H+ + H: 10P/156H (excitation) (icludes 99ps) 156P/10 H (charge exchange) • He2++ H: 20P/156H (exc); 156P/20 (CX) • C6+ + H:120P/4H (CX) (before: 35P/1H) • O8+ + H: 84P/4H (CX) (before: 45P/1H)
PartⅠ: H++H(1s) collision system Electron capture to 1s, 2s and 2p states of H
Part Ⅱ: He2+ + H(1s) collision system: Energy dependence of state-selective cross sections for electron capture to 1s, 2l, 3l and 4l states of He+.
Partial electron capture cross sections to He+(n), n = 1, 2, 3, 4.
Total charge transfer cross section for He2++H (1s) collision
Total electron capture cross sections for C6++H (1s) collisions
Part Ⅳ: O8++H(1s) collision system Partial electron capture cross sections to O7+(n), n=4, 5, 6.
Energy dependence of state-selective cross sections for electron capture to 4l states of O7+
State-selective cross sections for electron capture to 5l states of O7+
State-selective cross sections for electron capture to 6l states of O7+.
Total charge transfer cross sections for O8++H (1s) collisions