Fundamental World of Quantum Chemistry: A Tribute to the Memory of Per-Olov Löwdin, Volume 3Erkki J. Brändas, Eugene S. Kryachko Per-Olov Löwdin's stature has been a symbol of the world of quantum theory during the past five decades, through his basic contributions to the development of the conceptual framework of Quantum Chemistry and introduction of the fundamental concepts; through a staggering number of regular summer schools, winter institutes, innumerable lectures at Uppsala, Gainesville and elsewhere, and Sanibel Symposia; by founding the International Journal of Quantum Chemistry and Advances in Quantum Chemistry; and through his vision of the possible and his optimism for the future, which has inspired generations of physicists, chemists, mathematicians, and biologists to devote their lives to molecular electronic theory and dynamics, solid state, and quantum biology. Fundamental World of Quantum Chemistry: Volumes I, II and III form a collection of papers dedicated to the memory of Per-Olov Löwdin. These volumes are of interest to a broad audience of quantum, theoretical, physical, biological, and computational chemists; atomic, molecular, and condensed matter physicists; biophysicists; mathematicians working in many-body theory; and historians and philosophers of natural science. The volumes will be accessible to all levels, from students, PhD students, and postdocs to their supervisors. |
Contents
G G Hall | 1 |
Independent Particle Models 372 | 3 |
Macroscopic Quantum Tunneling a Natural OrbitalOccupation | 5 |
Conclusions | 16 |
Complex Extensions of Some Real Lie Algebras | 19 |
Hermitian quantum mechanics | 26 |
One and Two Particle States | 30 |
References | 32 |
Extending the Concept of Chemical Bond | 399 |
References | 401 |
Goidenko and L Labzowsky | 406 |
Hubac and S Wilson | 407 |
Reactions of Nitrous Oxide with Lithium and Copper | 408 |
Conclusion | 419 |
B Roos P Å Malmqvist and L Cagliardi | 425 |
BrillouinWigner Perturbation Theory and the ManyBody Problem | 426 |
Linear JahnTeller Systems | 54 |
Lie Symmetry and the Geometric Phase effect in JahnTeller Systems | 63 |
R Kibler and M Daoud | 67 |
HF Equations and Thouless Stability Conditions | 75 |
A General Supersymmetric Hamiltonian | 77 |
A Fractional Supersymmetric Oscillator | 84 |
Classification of BrokenSymmetry Solutions | 85 |
Differential Realizations | 86 |
Symmetry Restricted HF Equations and Stability Conditions | 92 |
Concluding remarks | 98 |
Definition of the Atomic SpectralProduct Basis | 99 |
Applications | 106 |
Concluding Remarks | 113 |
Surface | 114 |
Dedication | 115 |
O E Alon and L S Cederbaum | 117 |
Concluding Remarks | 123 |
Acknowledgments | 126 |
P R Surján and Á Szabados | 129 |
B SpinIndependent Matrix Elements | 130 |
SymmetryBased Factorization of the OSGF | 132 |
F A Matsen | 141 |
Triplet States | 145 |
Analytical Continuation of the OSGF | 147 |
Using Noncanonical Orbital Energies in MBPT | 149 |
Catalysis | 161 |
Perturbation Corrections to Ionization Energies | 168 |
The Spin Projection Operator | 171 |
The Crossed Beam Experiment | 174 |
Conclusions | 177 |
The Pauli Exclusive Principle SpinStatistics Connection | 183 |
QuantumClassical Reduction of the Dynamical Operator | 184 |
Mayer and A Hamza | 187 |
Parastatistics and Statistics of Quasiparticles in a Periodical Lattice | 190 |
QuantumClassical Reduction of the Relaxation Operator | 192 |
Indistinguishability of Identical Particles and the Symmetry Postulate | 198 |
A Nicolaides | 199 |
The Expectation Value of the Electric Field at the Nuclei of a Molecule | 201 |
Some Contradictions with the Concept of Particle Identity and Their | 204 |
Conclusion | 207 |
Field Energy Density | 213 |
Comparison Between the ManyBody Perturbative and GreensFunction | 215 |
Srivastava | 221 |
Computations | 228 |
The Propagator or GreensFunction Method | 235 |
P Fulde | 241 |
Probability Current Density | 247 |
Pairing | 249 |
Conclusions | 253 |
Gaussian Wave Packet in Two Dimensions | 254 |
The TimeEvolution of Nonstationary States of Polyelectronic Atoms | 255 |
Earlier and More Recent Formulations | 258 |
Cuprate Layers Electrons and OffDiagonal LongRange Order | 260 |
J Avery | 261 |
Generalized angular momentum | 267 |
Discussion | 269 |
R Krems and A Dalgarno | 273 |
Gegenbauer polynomials | 280 |
Collisions of EMolecules and SAtoms with Hyperfine Interaction | 286 |
98 | 292 |
References | 294 |
Intermediate Exciton Theory for the Electronic Spectra | 297 |
Sturmian Basis Sets for Atomic and Molecular Calculations | 300 |
The TwoState Model of SIN | 303 |
W P Reinhardt and H Perry | 305 |
Multiply Excited Bound and Resonance States of Atomic Negative | 307 |
Further Remarks and Conclusions | 313 |
Conclusions | 319 |
Malli | 323 |
Discontinuous Derivative Problem | 327 |
The Tunneling Problem | 331 |
SgBr and SgBr | 337 |
Number Analysis | 341 |
Molecular Structure and Matrix Manipulation | 349 |
Relativistic DirackFock SCF Calculations for Molecules | 352 |
Conclusions | 359 |
Acknowledgment | 367 |
Discussion | 369 |
The Intermediate Hamiltonian Method | 372 |
IPM Wavefunctions with the Correct Symmetries | 377 |
Superheavy Elements | 389 |
The Generalized Multistructural Wave Function GMS | 390 |
O Tishchenko E S Kryachko and M T Nguyen | 393 |
R Lefebvre and B Stern | 428 |
S R Gwaltney G J O Beran and M HeadGordon | 433 |
De Facto Apparently Irreversible Molecular Dynamics | 434 |
Summary | 438 |
Examples | 441 |
Molecular Chirality and de lege Parity Violation Space Reflection | 448 |
Excited States? | 449 |
Potential Energy Surfaces | 452 |
R McWeeny | 459 |
A Personal Recollection | 464 |
G Berthier M Defranceschi and C Le Bris | 467 |
Symmetry Considerations | 470 |
J P Dahl | 474 |
F J Luque A BidonChanal J MuñozMuriedas I Soteras C Curutchet | 475 |
Acknowledgments | 480 |
References | 484 |
Application of Fractional Models in Drug Design | 489 |
Geometric Formulation | 491 |
Integral Equations for Functions At and Bt | 504 |
Method Evaluation | 505 |
Spin Labels | 515 |
Acknowledgments | 518 |
Densities | 519 |
O Dolgounitcheva V G Zakrzewski and J V Ortiz | 525 |
The Method | 531 |
eLiH | 537 |
Dedication | 539 |
The Multichannel Wave Function of the Hydrogen Atom | 543 |
Conclusion | 550 |
Results and Discussion | 551 |
Conclusions | 552 |
Ionization of WatsonCrick Base Pairs | 559 |
References | 560 |
Kth Order Approximations for States | 563 |
Introduction | 564 |
Cationization of WatsonCrick Base Pairs | 567 |
Conclusions | 576 |
Conclusions | 578 |
The Fundamental Optimization Theorem | 579 |
Concluding Remarks | 582 |
References | 584 |
A J Thakkar and T Koga Analytical HartreeFock Wave Functions for Atoms and Ions | 587 |
Singlezeta Wave Functions | 588 |
Doublezeta Wave Functions | 590 |
Sequential Monte | 591 |
Conclusion | 593 |
Heavy Atoms | 595 |
| 596 | |
Summary | 597 |
| 598 | |
E Clementi and G Corongiu The Origin of the Molecular Atomization Energy Explained with the HF and HFCC Models | 601 |
Introduction | 602 |
Scaling the HartreeFock Energy | 603 |
Analyses of the Correlation Energy from Experiments and HF Computations | 604 |
The WeylWigner Representation 240 | 606 |
Hydrogen Bonding Detour to DNArt | 607 |
The Scaling Factor for Atomic Systems | 608 |
Aziridine Isotope Effects | 609 |
Scaling Factor for an Atom in a Molecular System | 610 |
Validation of the Molecular Scaling Functional | 612 |
The Correlation Energy from HFCC and HF Computations | 614 |
| 616 | |
Van der Waals Interactions | 617 |
Conclusions | 619 |
Acknowledgment | 620 |
Results and Discussion | 622 |
References | 627 |
P Politzer Some Exact Energy Relationships | 631 |
Molecular Energies | 632 |
Interaction Energies | 635 |
Discussion and Summary | 636 |
The role of the olefin on the catalytic activity and regioselectivity | 637 |
Classical Orbits of Valence Electrons in Atoms | 640 |
| 642 | |
Effective OneElectron Potential in Atoms | 647 |
Conclusion | 651 |
Some Pertinent Problems Solved Long Ago or Just Recently | 653 |
Conclusion | 660 |
Notes | 662 |
| 665 | |
| 671 | |
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Common terms and phrases
algebra angular momentum antisymmetric approximation atoms basis set bond bosonic Brändas charge Chem chemical coefficients collisions configuration contributions convergence coordinates corresponding coupled cluster defined DF SCF diagonal effects eigenvalue electron affinity electron correlation equation excited experimental formula Gaussian geometry Hamiltonian matrix Hartree-Fock hydrogen hydrosilylation integrals interaction ionization potentials irrep k-fermions Kryachko Lett level shifts ligand linear many-body matrix elements MCSTEP method molecular molecules nuclear obtained operators optimized partitioning orbital energies parameters particle Per-Olov Löwdin Phys physics positron predicted problem Quantum Chem Quantum Chemistry quantum mechanics relativistic representation SCF calculations Schrödinger solution space spectral-product basis spinors structure subspace superheavy superheavy elements supersymmetric symmetry Table theoretical total spin transformation valence values vibrational vibronic coupling wave function wavefunction zero order