Photosynthetic excitons / Herbert van Amerongen, Leonas Valkunas, Rienk van Grondelle.
Material type:![Text](/opac-tmpl/lib/famfamfam/BK.png)
- text
- computer
- online resource
- 9789812813664
- 9812813667
- Excitons
- Exciton theory
- Photosynthesis
- Electronic excitation
- Energy transfer
- Molecular spectroscopy
- Excitons
- Photosynthèse
- Excitation électronique
- Transfert d'énergie
- Spectroscopie moléculaire
- SCIENCE -- Life Sciences -- Biochemistry
- Electronic excitation
- Energy transfer
- Exciton theory
- Molecular spectroscopy
- Photosynthesis
- Exziton
- Photosynthese
- Energietransfer Mikrophysik
- Photosynthesepigment
- Photosystem
- Excitonen
- Fotosynthese
- 572.6 22
- QC176.8.E9 A44 2000eb
- 35.16
- 42.13
- UP 3710
- WN 3100
- WN 3150
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OPJGU Sonepat- Campus | E-Books EBSCO | Available |
Includes bibliographical references and index.
Print version record.
Preface; Contents; CHAPTER 1 INTRODUCTION: STRUCTURAL ORGANIZATION, SPECTRAL PROPERTIES AND EXCITATION ENERGY TRANSFER IN PHOTOSYNTHESIS; 1. Introduction; 1.1 Disordered vs. ordered light-harvesting systems; 2. The photosynthetic pigments: chlorophylls, bacteriochlorophylls and carotenoids; 2.1 The chlorophylls; 2.2 The bacteriochlorophylls; 2.3 The carotenoids; 3. The structure and function of important photosynthetic pigment-protein complexes; 3.1 The bacterial photosynthetic reaction center; 3.2 The reaction centers of Photosystem II and Photosystem I.
3.3 The peripheral light-harvesting complex (LH2) of photosynthetic purple bacteria3.4 The Fenna-Matthews-Olson protein of green sulphur bacteria; 3.5 LHCII, the major chlorophyll binding light-harvesting complex of plants; 3.6 The core antenna and reaction center of Photosystem I; 4. Mechanism of Energy Transfer and Trapping in Photosynthesis; 4.1 The Forster equation; 4.2 Trapping by the reaction center; 5. Energy transfer in some photosynthetic systems; 5.1 Energy transfer in the peripheral and core antennae of photosynthetic purple bacteria.
5.2 Energy transfer in the Fenna-Matthews-Olson complex5.3 Energy transfer in the major peripheral plant light-harvesting complex LHCII; 5.4 Energy transfer in Photosystem I; 6. Conclusions; References; CHAPTER 2 THE EXCITON CONCEPT; 1. Historical overview; 2. Interactions between molecules; 3. The excitonically coupled dimer; 3.1 Non-equivalent site energies; 3.2 Transition dipole moment; 4. Excitonic interactions in larger systems; 5. Molecular crystals; 6. Molecular and lattice vibrations and loss of exciton coherence; References.
CHAPTER 3 SOME OPTICAL PROPERTIES OF THE EXCITONICALLY COUPLED DIMER1. Introduction; 2. Linear dichroism; 3. Circular dichroism; 4. Fluorescence; 5. Fluorescence anisotropy; 6. Transient absorption (pump-probe); 7. Triplet-minus-singlet spectroscopy; 8. Stark spectroscopy; 9. A hypothetical dimer; 10. B820: an excitonically coupled dimer from photosynthetic purple bacteria; 11. Spectroscopic properties of B820; Appendix 3.1: Derivation of expressions for linear dichroism; Appendix 3.2: Derivation of expression for anisotropy; References; CHAPTER 4 MIXING WITH HIGHER EXCITED STATES.
1. Introduction2. Absorption; 2.1 Ground-state absorption; 2.2 Excited-state absorption and transient absorption; 2.3 Non-degenerate dimer; 3. Circular dichroism; 4. Circular dichroism of B820; References; CHAPTER 5 SPECTRAL SHAPES: HOMOGENEOUS AND INHOMOGENEOUS BROADENING; 1. Introduction; 2. The coupling of vibrations and phonons to electronic transitions; 2.1 Adiabatic approach; 2.2 Transition dipole moment; 2.3 Absorption spectrum; 2.4 Electron-phonon coupling; 2.5 Brownian oscillator model; 3. Homogeneous and inhomogeneous broadening; 4. Exciton coupling and spectral broadening.
Excitons are considered as the basic concept used by describing the spectral properties of photosynthetic pigment-protein complexes and excitation dynamics in photosynthetic light-harvesting antenna and reaction centers. Following the recently obtained structures of a variety of photosynthetic pigment-protein complexes from plants and bacteria our interest in understanding the relation between structure, function and spectroscopy has strongly increased. These data demonstrate a short interpigment distance (of the order of 1 nm or even smaller) and/or a highly symmetric (ring-like) arrangement.
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