State of The Art of Molecular Electronic Structure Computations: Correlation Methods, Basis Sets and More
Specificaties
Gebonden, blz.
|
Engels
Elsevier Science |
e druk, 2019
ISBN13: 9780128161746
Rubricering
Onderdeel van serie
Advances in Quantum Chemistry
Levertijd ongeveer 8 werkdagen
Samenvatting
State of the Art of Molecular Electronic Structure Computations: Correlation Methods, Basis Sets and More, Volume 79 in the Advances in Quantum Chemistry series, presents surveys of current topics in this rapidly developing field that has emerged at the cross section of the historically established areas of mathematics, physics, chemistry and biology. Chapters in this new release include Computing accurate molecular properties in real space using multiresolution analysis, Self-consistent electron-nucleus cusp correction for molecular orbitals, Correlated methods for computational spectroscopy, Potential energy curves for the NaH molecule and its cation with the cock space coupled cluster method, and much more.
Specificaties
Inhoudsopgave
<p>1. Computing accurate molecular properties in real space using multiresolution analysis</p> <p>Florian A. Bischoff</p> <p>2. Hypergeometric orthogonal polynomials as expansion basis sets for atomic and molecular orbitals: The Jacobi ladder</p> <p>Cecilia Coletti, Vincenzo Aquilanti and Federico Palazzetti</p> <p>3. Two-dimensional Sturmian basis set for bound state calculations</p> <p>Juan Martin Randazzo and Lorenzo Ugo Ancarani</p> <p>4. Normalizing cluster wavefunctions in the interstitial region within the muffin-tin approximation</p> <p>Daniel Gebremedhin, Charles Weatherford and Brian Wilson</p> <p>5. Self-consistent electron–nucleus cusp correction for molecular orbitals</p> <p>Pierre-Francois Loos, Anthony Scemama and Michel Caffarel</p> <p>6. Configuration interaction study of the <SUP>3</SUP>P ground and low-lying states of the boron anion: The boron electron affinity</p> <p>María Belén Ruiz</p> <p>7. Advances in approximate natural orbital functional theory</p> <p>Ion Mitxelena, Mario Piris and Jesus M. Ugalde</p> <p>8. Collision processes in atoms and molecules using effective potentials</p> <p>Alejandra M.P. Mendez, Dario M. Mitnik and Jorge E. Miraglia</p> <p>9. Unified construction of Fermi, Pauli, and exchange-correlation potentials</p> <p>Viktor N. Staroverov and Egor Ospadov</p> <p>10. Potential energy curves of the NaH molecule and its cation with the Fock space coupled cluster method</p> <p>Artur Lison, Monika Musial and Stanislaw A. Kucharski</p> <p>11. An analysis of the performance of coupled cluster methods for K-edge core excitations and ionizations using standard basis sets</p> <p>Johanna P. Carbone, Lan Cheng, Rolf H. Myhre, Devin Matthews, Henrik Koch and Sonia Coriani</p> <p>12. Determination of electronic couplings in the singlet fission process using a nonorthogonal configuration interaction approach</p> <p>Luis Enrique Aguilar Suarez, R. K. Kathir, Enrico Siagri, Remco W. A. Havenith and Shirin Faraji</p> <p>13. Diagnosis of two evaluation paths to density-based descriptors of molecular electronic transitions</p> <p>Gabriel Breuil, Kaltrina Shehu, Elise Lognon, Sylvain Pitie, Benjamin Lasorne</p> <p>and Thibaud Etienne</p> <p>14. Physisorption energy of H and H2 on clean Pt(111) as a useful surface energy reference in Quantum Monte Carlo calculation</p> <p>Rajesh O. Sharma and Philip E. Hoggan</p> <p>15. Stability after confinement of the H atom</p> <p>Milagros F. Morcillo, Enrique F. Borja, Jose M. Alcaraz-Pelegrina and</p> <p>Antonio Sarsa</p>