Functional molecular materials : an introductory textbook / Matteo Atzori, Flavia Artizzu

Von:

Atzori, Matteo [VerfasserIn]

Mitwirkende(r):

Artizzu, Flavia [VerfasserIn]

Resource type: Ressourcentyp: Buch (Online)Buch (Online)Sprache: Englisch Verlag: Singapore : Pan Stanford Publishing, [2018]Beschreibung: 1 Online-RessourceISBN:

1351233653
9781351233651

Schlagwörter:

Andere physische Formen: 9789814774765 | Erscheint auch als: Functional molecular materials. Druck-Ausgabe Singapore : Pan Stanford Publishing, 2018. xii, 400 SeitenDDC-Klassifikation:

539.7

LOC-Klassifikation:

QC173

Online-Ressourcen:

Zugang im Netz des KIT

Zusammenfassung: 2.1.5 Electronic Magnetic Moments2.1.5.1 Classical model of magnetic moments; 2.1.5.2 Quantum mechanical model of magnetic moments; 2.1.6 Magnetic Properties of Free Atoms; 2.1.6.1 Hund's rules: Occupancy of available electronic states (Russell-Saunders scheme; 2.1.6.2 Quenching of the orbital angular momentum L; 2.1.7 The Curie Law; 2.1.8 The Curie-Weiss Law; 2.1.9 Deviations from the Curie Law; 2.1.10 Effective Magnetic Moment and .T Value; 2.1.11 Field Dependence of Magnetization; 2.1.12 Magnetic Exchange Coupling; 2.1.13 Magnetic Exchange Coupling in a Dinuclear CompoundZusammenfassung: 2.1.14 Multicenter Magnetic Systems and Spin Hamiltonian Approach2.2 Transport Properties of Molecular Materials; 2.2.1 Electrical Conductivity; 2.2.2 Classes of Conducting Materials; 2.2.3 Energy Bands and Origin of Transport Properties; 2.2.4 Thermal Dependence of Conductivity; 2.2.5 Types of Semiconducting Materials: Chemical and Electrochemical Doping; 2.2.6 Band Theory of Solids: A Closer Look at the Band Structure; 2.2.7 Structural Anisotropy and Peierls Distortion; 2.3 Principles of Molecular Photophysics; 2.3.1 Electromagnetic Radiation and Light-Matter InteractionZusammenfassung: 2.3.2 Electronic Energy States2.3.2.1 Electronic, rotational, and vibrational states; 2.3.2.2 Absorption of radiation; 2.3.2.3 Transition moment integral and selection rules; 2.3.2.4 The Franck-Condon principle; 2.3.3 Evolution of Excited States; 2.3.3.1 Luminescence; 2.3.3.2 Kasha's rule; 2.3.3.3 Fluorescence and phosphorescence; 2.3.3.4 Luminescent and nonluminescent molecules; 2.3.3.5 Jablonski diagram; 2.3.4 Emission Efficiency; 2.3.4.1 Quantum yield and luminescence quenching; 2.3.4.2 Kinetics of photophysical processes; 2.3.4.3 Emission lifetimeZusammenfassung: 2.3.4.4 Dynamics of radiative decay2.3.5 Energy Transfer; 2.3.5.1 Dexter's energy transfer; 2.3.5.2 Förster's energy transfer; 2.3.6 Quenching; 2.3.6.1 Dynamic and static quenching; 2.3.7 Metal-Centered Electronic Transitions; 2.3.7.1 d-d transitions; 2.3.7.2 f-f transitions; 2.3.8 Nonlinear Molecular Optics; Chapter 3. Functional Molecular Materials; 3.1 Magnetic Molecular Materials; 3.1.1 Paramagnetism; 3.1.2 Ferromagnetism; 3.1.3 Antiferromagnetism; 3.1.4 Ferrimagnetism; 3.1.5 Spin Crossover; 3.1.6 Valence Tautomerism; 3.1.7 Slow Magnetic Relaxation; 3.1.7.1 Single-molecule magnetsZusammenfassung: Cover; Half title; Title; Copyright; Contents; Preface; Chapter 1. Introduction to Molecular Materials; 1.1 What Are Molecular Materials; 1.2 The Versatility of Molecular Chemistry; 1.3 Top-Down and Bottom-Up Approaches; 1.4 Dimensions and Dimensionalities; 1.5 A Guide to Design Functional Molecular Materials; Chapter 2. Background; 2.1 Basic Concepts of Magnetism, Magnetochemistry, and Molecular Magnetism; 2.1.1 Magnetic Field; 2.1.2 Magnetic Induction; 2.1.3 Magnetic Moment; 2.1.4 Effect of Magnetic Field on Matter; 2.1.4.1 Magnetization; 2.1.4.2 Magnetic permeability and susceptibilityPPN: PPN: 1026371406Package identifier: Produktsigel: ZDB-4-NLEBK

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