Molecular excitation dynamics and relaxation : quantum theory and spectroscopy / / Leonas Valkunas, Darius Abramavicius, Tomas Mancal |
Autore | Valkunas Leonas |
Edizione | [1st ed.] |
Pubbl/distr/stampa | Weiheim, Germany, : Wiley-VCH, c2013 |
Descrizione fisica | 1 online resource (465 p.) |
Disciplina | 543.54 |
Altri autori (Persone) |
AbramaviciusDarius
MancalTomas |
Collana | Wiley trading series |
Soggetto topico |
Condensed matter - Spectra
Molecular spectroscopy Quantum theory |
ISBN |
3-527-65367-8
3-527-65365-1 3-527-65368-6 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Molecular Excitation Dynamics and Relaxation; Contents; Preface; Part One Dynamics and Relaxation; 1 Introduction; 2 Overview of Classical Physics; 2.1 Classical Mechanics; 2.1.1 Concepts of Theoretical Mechanics: Action, Lagrangian, and Lagrange Equations; 2.1.2 Hamilton Equations; 2.1.3 Classical Harmonic Oscillator; 2.2 Classical Electrodynamics; 2.2.1 Electromagnetic Potentials and the Coulomb Gauge; 2.2.2 Transverse and Longitudinal Fields; 2.3 Radiation in Free Space; 2.3.1 Lagrangian and Hamiltonian of the Free Radiation; 2.3.2 Modes of the Electromagnetic Field
2.4 Light-Matter Interaction2.4.1 Interaction Lagrangian and Correct Canonical Momentum; 2.4.2 Hamiltonian of the Interacting Particle-Field System; 2.4.3 Dipole Approximation; 3 Stochastic Dynamics; 3.1 Probability and Random Processes; 3.2 Markov Processes; 3.3 Master Equation for Stochastic Processes; 3.3.1 Two-Level System; 3.4 Fokker-Planck Equation and Diffusion Processes; 3.5 Deterministic Processes; 3.6 Diffusive Flow on a Parabolic Potential (a Harmonic Oscillator); 3.7 Partially Deterministic Process and the Monte Carlo Simulation of a Stochastic Process 3.8 Langevin Equation and Its Relation to the Fokker-Planck Equation4 Quantum Mechanics; 4.1 Quantum versus Classical; 4.2 The Schrödinger Equation; 4.3 Bra-ket Notation; 4.4 Representations; 4.4.1 Schrödinger Representation; 4.4.2 Heisenberg Representation; 4.4.3 Interaction Representation; 4.5 Density Matrix; 4.5.1 Definition; 4.5.2 Pure versus Mixed States; 4.5.3 Dynamics in the Liouville Space; 4.6 Model Systems; 4.6.1 Harmonic Oscillator; 4.6.2 Quantum Well; 4.6.3 Tunneling; 4.6.4 Two-Level System; 4.6.5 Periodic Structures and the Kronig-Penney Model; 4.7 Perturbation Theory 4.7.1 Time-Independent Perturbation Theory4.7.2 Time-Dependent Perturbation Theory; 4.8 Einstein Coefficients; 4.9 Second Quantization; 4.9.1 Bosons and Fermions; 4.9.2 Photons; 4.9.3 Coherent States; 5 Quantum States of Molecules and Aggregates; 5.1 Potential Energy Surfaces, Adiabatic Approximation; 5.2 Interaction between Molecules; 5.3 Excitonically Coupled Dimer; 5.4 Frenkel Excitons of Molecular Aggregates; 5.5 Wannier-Mott Excitons; 5.6 Charge-Transfer Excitons; 5.7 Vibronic Interaction and Exciton Self-Trapping; 5.8 Trapped Excitons; 6 The Concept of Decoherence 6.1 Determinism in Quantum Evolution6.2 Entanglement; 6.3 Creating Entanglement by Interaction; 6.4 Decoherence; 6.5 Preferred States; 6.6 Decoherence in Quantum Random Walk; 6.7 Quantum Mechanical Measurement; 6.8 Born Rule; 6.9 Everett or Relative State Interpretation of Quantum Mechanics; 6.10 Consequences of Decoherence for Transfer and Relaxation Phenomena; 7 Statistical Physics; 7.1 Concepts of Classical Thermodynamics; 7.2 Microstates, Statistics, and Entropy; 7.3 Ensembles; 7.3.1 Microcanonical Ensemble; 7.3.2 Canonical Ensemble; 7.3.3 Grand Canonical Ensemble 7.4 Canonical Ensemble of Classical Harmonic Oscillators |
Record Nr. | UNINA-9910812960203321 |
Valkunas Leonas | ||
Weiheim, Germany, : Wiley-VCH, c2013 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Molecular excitation dynamics and relaxation [[electronic resource] ] : quantum theory and spectroscopy / / Leonas Valkunas, Darius Abramavicius, Tomas Mancal |
Autore | Valkūnas Leonas |
Pubbl/distr/stampa | Weiheim, Germany, : Wiley-VCH, c2013 |
Descrizione fisica | 1 online resource (465 p.) |
Disciplina | 543.54 |
Altri autori (Persone) |
AbramaviciusDarius
MancalTomas |
Collana | Wiley trading series |
Soggetto topico |
Condensed matter - Spectra
Molecular spectroscopy Quantum theory |
ISBN |
3-527-65367-8
3-527-65365-1 3-527-65368-6 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Molecular Excitation Dynamics and Relaxation; Contents; Preface; Part One Dynamics and Relaxation; 1 Introduction; 2 Overview of Classical Physics; 2.1 Classical Mechanics; 2.1.1 Concepts of Theoretical Mechanics: Action, Lagrangian, and Lagrange Equations; 2.1.2 Hamilton Equations; 2.1.3 Classical Harmonic Oscillator; 2.2 Classical Electrodynamics; 2.2.1 Electromagnetic Potentials and the Coulomb Gauge; 2.2.2 Transverse and Longitudinal Fields; 2.3 Radiation in Free Space; 2.3.1 Lagrangian and Hamiltonian of the Free Radiation; 2.3.2 Modes of the Electromagnetic Field
2.4 Light-Matter Interaction2.4.1 Interaction Lagrangian and Correct Canonical Momentum; 2.4.2 Hamiltonian of the Interacting Particle-Field System; 2.4.3 Dipole Approximation; 3 Stochastic Dynamics; 3.1 Probability and Random Processes; 3.2 Markov Processes; 3.3 Master Equation for Stochastic Processes; 3.3.1 Two-Level System; 3.4 Fokker-Planck Equation and Diffusion Processes; 3.5 Deterministic Processes; 3.6 Diffusive Flow on a Parabolic Potential (a Harmonic Oscillator); 3.7 Partially Deterministic Process and the Monte Carlo Simulation of a Stochastic Process 3.8 Langevin Equation and Its Relation to the Fokker-Planck Equation4 Quantum Mechanics; 4.1 Quantum versus Classical; 4.2 The Schrödinger Equation; 4.3 Bra-ket Notation; 4.4 Representations; 4.4.1 Schrödinger Representation; 4.4.2 Heisenberg Representation; 4.4.3 Interaction Representation; 4.5 Density Matrix; 4.5.1 Definition; 4.5.2 Pure versus Mixed States; 4.5.3 Dynamics in the Liouville Space; 4.6 Model Systems; 4.6.1 Harmonic Oscillator; 4.6.2 Quantum Well; 4.6.3 Tunneling; 4.6.4 Two-Level System; 4.6.5 Periodic Structures and the Kronig-Penney Model; 4.7 Perturbation Theory 4.7.1 Time-Independent Perturbation Theory4.7.2 Time-Dependent Perturbation Theory; 4.8 Einstein Coefficients; 4.9 Second Quantization; 4.9.1 Bosons and Fermions; 4.9.2 Photons; 4.9.3 Coherent States; 5 Quantum States of Molecules and Aggregates; 5.1 Potential Energy Surfaces, Adiabatic Approximation; 5.2 Interaction between Molecules; 5.3 Excitonically Coupled Dimer; 5.4 Frenkel Excitons of Molecular Aggregates; 5.5 Wannier-Mott Excitons; 5.6 Charge-Transfer Excitons; 5.7 Vibronic Interaction and Exciton Self-Trapping; 5.8 Trapped Excitons; 6 The Concept of Decoherence 6.1 Determinism in Quantum Evolution6.2 Entanglement; 6.3 Creating Entanglement by Interaction; 6.4 Decoherence; 6.5 Preferred States; 6.6 Decoherence in Quantum Random Walk; 6.7 Quantum Mechanical Measurement; 6.8 Born Rule; 6.9 Everett or Relative State Interpretation of Quantum Mechanics; 6.10 Consequences of Decoherence for Transfer and Relaxation Phenomena; 7 Statistical Physics; 7.1 Concepts of Classical Thermodynamics; 7.2 Microstates, Statistics, and Entropy; 7.3 Ensembles; 7.3.1 Microcanonical Ensemble; 7.3.2 Canonical Ensemble; 7.3.3 Grand Canonical Ensemble 7.4 Canonical Ensemble of Classical Harmonic Oscillators |
Record Nr. | UNINA-9910141800503321 |
Valkūnas Leonas | ||
Weiheim, Germany, : Wiley-VCH, c2013 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|