Advances in Quantum Chemistry
Theory of Confined Quantum Systems - Part One
Herausgegeben:Sabin, John R.; Brändas, Erkki J.
Advances in Quantum Chemistry
Theory of Confined Quantum Systems - Part One
Herausgegeben:Sabin, John R.; Brändas, Erkki J.
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Advances in Quantum Chemistry presents surveys of current developments in this rapidly developing field. With invited reviews written by leading international researchers, each presenting new results, it provides a single vehicle for following progress in this interdisciplinary area.
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Advances in Quantum Chemistry presents surveys of current developments in this rapidly developing field. With invited reviews written by leading international researchers, each presenting new results, it provides a single vehicle for following progress in this interdisciplinary area.
Produktdetails
- Produktdetails
- Advances in Quantum Chemistry Volume 57
- Verlag: Academic Press / Elsevier Science & Technology
- Artikelnr. des Verlages: S0065-3276(09)X0005-5
- Englisch
- Abmessung: 19mm x 152mm x 229mm
- Gewicht: 610g
- ISBN-13: 9780123747648
- Artikelnr.: 26181473
- Advances in Quantum Chemistry Volume 57
- Verlag: Academic Press / Elsevier Science & Technology
- Artikelnr. des Verlages: S0065-3276(09)X0005-5
- Englisch
- Abmessung: 19mm x 152mm x 229mm
- Gewicht: 610g
- ISBN-13: 9780123747648
- Artikelnr.: 26181473
John R. Sabin is Professor of Physics and Chemistry Emeritus at the University of Florida, and Adjungeret Professor at the University of Southern Denmark. He received the AB degree from Williams College in 1962 and the PhD from the University of New Hampshire in 1966. Thereafter he was a postdoctoral student at Uppsala University and at Northwestern University. He was Assistant Professor at the University of Missouri for three years (1968-1971) and then came to the University of Florida where he has been since.
Sabin's research interest is in the theoretical description of the interaction of fast charged baryon projectiles with atomic and molecular targets, both as neutrals and ions. In this work, he uses molecular quantum mechanics to describe such interactions. In particular, he is interested in the mechanism of absorption of the projectile's mechanical energy by the target, where it is mostly converted to electronic energy, which is measured by the target's mean excitation energy. He has written some 250 articles in this and related fields.
Sabin is editor of Advances in Quantum Chemistry and has been editor of the International Journal of Quantum Chemistry. He has edited some 90 volumes and proceedings.
Sabin's research interest is in the theoretical description of the interaction of fast charged baryon projectiles with atomic and molecular targets, both as neutrals and ions. In this work, he uses molecular quantum mechanics to describe such interactions. In particular, he is interested in the mechanism of absorption of the projectile's mechanical energy by the target, where it is mostly converted to electronic energy, which is measured by the target's mean excitation energy. He has written some 250 articles in this and related fields.
Sabin is editor of Advances in Quantum Chemistry and has been editor of the International Journal of Quantum Chemistry. He has edited some 90 volumes and proceedings.
Properties of confined hydrogen and helium atoms (S. Patil and Y.P. Varshni)
Exact relations for confined one-electron systems (K.D. Sen, V.I. Pupyshev, and H.E. Montgomery Jr.)
The hydrogen atom confined in semi-infinite spaces limited by conoidal boundaries (E. Ley-Koo)
The hydrogen and helium atoms confined in spherical boxes (N. Aquino)
Exact solutions for confined model systems using Kummer functions (B.L. Burrows and M. Cohen)
Perturbation theory for a hydrogen-like atom confined within an impenetrable spherical cavity (C. Laughlin)
Comparative study between the Hartree-Fock and Kohn-Sham models for the lowest singlet and triplet states of the confined helium atom (J. Garza and R. Vargas)
Thomas-Fermi-Dirac-Weizsäcker density functional formalism applied to the study of many-electron atom confinement by open and closed boundaries (S.A. Cruz)
Confined atoms treated as open quantum systems (R.F.W. Bader)
Modeling pressure effects on the electronic properties of Ca, Sr and Ba by the confined atom model (D. Guerra, R. Vargas, P. Fuentealba, and J. Garza)
Photoionization of atoms encaged in spherical fullerenes (V.K. Dolmatov)
DFT study of molecules confined inside fullerene and fullerene-like cages (O.P. Charkin, N.M. Klimenko, and D.O. Charkin)
Spectroscopy of confined atomic systems: effect of plasma (A.N. Sil, S. Canuto and P.K. Mukherjee)
The energy level structure of low-dimensional multi-electron quantum dots (T. Sako, J. Paldus and G.H.F. Diercksen)
Engineering quantum confined silicon nanostructures: ab-initio study of the structural, electronic and optical properties (E. Degoli and S. Ossicini)
Exact relations for confined one-electron systems (K.D. Sen, V.I. Pupyshev, and H.E. Montgomery Jr.)
The hydrogen atom confined in semi-infinite spaces limited by conoidal boundaries (E. Ley-Koo)
The hydrogen and helium atoms confined in spherical boxes (N. Aquino)
Exact solutions for confined model systems using Kummer functions (B.L. Burrows and M. Cohen)
Perturbation theory for a hydrogen-like atom confined within an impenetrable spherical cavity (C. Laughlin)
Comparative study between the Hartree-Fock and Kohn-Sham models for the lowest singlet and triplet states of the confined helium atom (J. Garza and R. Vargas)
Thomas-Fermi-Dirac-Weizsäcker density functional formalism applied to the study of many-electron atom confinement by open and closed boundaries (S.A. Cruz)
Confined atoms treated as open quantum systems (R.F.W. Bader)
Modeling pressure effects on the electronic properties of Ca, Sr and Ba by the confined atom model (D. Guerra, R. Vargas, P. Fuentealba, and J. Garza)
Photoionization of atoms encaged in spherical fullerenes (V.K. Dolmatov)
DFT study of molecules confined inside fullerene and fullerene-like cages (O.P. Charkin, N.M. Klimenko, and D.O. Charkin)
Spectroscopy of confined atomic systems: effect of plasma (A.N. Sil, S. Canuto and P.K. Mukherjee)
The energy level structure of low-dimensional multi-electron quantum dots (T. Sako, J. Paldus and G.H.F. Diercksen)
Engineering quantum confined silicon nanostructures: ab-initio study of the structural, electronic and optical properties (E. Degoli and S. Ossicini)
Properties of confined hydrogen and helium atoms (S. Patil and Y.P. Varshni)
Exact relations for confined one-electron systems (K.D. Sen, V.I. Pupyshev, and H.E. Montgomery Jr.)
The hydrogen atom confined in semi-infinite spaces limited by conoidal boundaries (E. Ley-Koo)
The hydrogen and helium atoms confined in spherical boxes (N. Aquino)
Exact solutions for confined model systems using Kummer functions (B.L. Burrows and M. Cohen)
Perturbation theory for a hydrogen-like atom confined within an impenetrable spherical cavity (C. Laughlin)
Comparative study between the Hartree-Fock and Kohn-Sham models for the lowest singlet and triplet states of the confined helium atom (J. Garza and R. Vargas)
Thomas-Fermi-Dirac-Weizsäcker density functional formalism applied to the study of many-electron atom confinement by open and closed boundaries (S.A. Cruz)
Confined atoms treated as open quantum systems (R.F.W. Bader)
Modeling pressure effects on the electronic properties of Ca, Sr and Ba by the confined atom model (D. Guerra, R. Vargas, P. Fuentealba, and J. Garza)
Photoionization of atoms encaged in spherical fullerenes (V.K. Dolmatov)
DFT study of molecules confined inside fullerene and fullerene-like cages (O.P. Charkin, N.M. Klimenko, and D.O. Charkin)
Spectroscopy of confined atomic systems: effect of plasma (A.N. Sil, S. Canuto and P.K. Mukherjee)
The energy level structure of low-dimensional multi-electron quantum dots (T. Sako, J. Paldus and G.H.F. Diercksen)
Engineering quantum confined silicon nanostructures: ab-initio study of the structural, electronic and optical properties (E. Degoli and S. Ossicini)
Exact relations for confined one-electron systems (K.D. Sen, V.I. Pupyshev, and H.E. Montgomery Jr.)
The hydrogen atom confined in semi-infinite spaces limited by conoidal boundaries (E. Ley-Koo)
The hydrogen and helium atoms confined in spherical boxes (N. Aquino)
Exact solutions for confined model systems using Kummer functions (B.L. Burrows and M. Cohen)
Perturbation theory for a hydrogen-like atom confined within an impenetrable spherical cavity (C. Laughlin)
Comparative study between the Hartree-Fock and Kohn-Sham models for the lowest singlet and triplet states of the confined helium atom (J. Garza and R. Vargas)
Thomas-Fermi-Dirac-Weizsäcker density functional formalism applied to the study of many-electron atom confinement by open and closed boundaries (S.A. Cruz)
Confined atoms treated as open quantum systems (R.F.W. Bader)
Modeling pressure effects on the electronic properties of Ca, Sr and Ba by the confined atom model (D. Guerra, R. Vargas, P. Fuentealba, and J. Garza)
Photoionization of atoms encaged in spherical fullerenes (V.K. Dolmatov)
DFT study of molecules confined inside fullerene and fullerene-like cages (O.P. Charkin, N.M. Klimenko, and D.O. Charkin)
Spectroscopy of confined atomic systems: effect of plasma (A.N. Sil, S. Canuto and P.K. Mukherjee)
The energy level structure of low-dimensional multi-electron quantum dots (T. Sako, J. Paldus and G.H.F. Diercksen)
Engineering quantum confined silicon nanostructures: ab-initio study of the structural, electronic and optical properties (E. Degoli and S. Ossicini)