Verfügbarkeit: Principles of physical chemistry

Principles of physical chemistry:

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Hauptverfasser:	Kuhn, Hans (VerfasserIn), Försterling, Horst-Dieter 1934- (VerfasserIn), Waldeck, David H. (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Hoboken, NJ Wiley 2009
Ausgabe:	2. ed.
Schlagworte:	Chemistry, Physical and theoretical Physikalische Chemie Lehrbuch
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	XLII, 1032 S. Ill., graph. Darst. 1 CD-ROM (12 cm)
ISBN:	9780471965411 9780470089644

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Datensatz im Suchindex

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adam_text	Titel: Principles of physical chemistry Autor: Kuhn, Hans Jahr: 2009 Contents List of Foundations, xxiii List of Justifications, xxix Preface, xxxiii Acknowledgments, xxxv Authors Biography, xxxvii List of Symbols, xxxix Introduction, 1 1 Wave-Particle Duality, 3 1.1 Overview of Quantum Mechanics, 3 1.1.1 Historical Highlights, 3 1.1.2 An Approach to Quantum Mechanics, 4 1.2 Light, 5 1.2.1 Particle Nature of Light: Photoelectric Effect, 6 1.2.2 Wave Nature of Light: Diffraction, 7 1.2.3 Interpretation of the Experiments, 12 1.3 Electrons, 12 1.3.1 Particle Nature of Electrons, 13 1.3.2 Wave Nature of Electrons, 13 1.3.3 Interpretation of the Experiments, 15 1.3.4 Formal Similarity Between Electron and Photon, 16 1.4 Questions Arising about Wave-Particle Duality, 16 1.4.1 Single Event—Probability Statement; Collective Behavior—Definite Statement, 16 1.4.2 Wave-Particle Duality and the Need to Abandon Familiär Ways of Thinking, 18 1.5 Conclusion, 20 2 Essential Aspects ofStructure and Bonding, 21 2.1 Introduction, 21 2.2 Distinct Energy States, 22 2.2.1 Atomic Spectra, 22 2.2.2 Franck-Hertz Experiment, 23 2.3 Standing Waves, 24 2.3.1 Particle Between Parallel Walls, 25 2.3.2 Ill-Posed Questions, 29 233 Electron in a Cubic Box, 29 vii viii CONTENTS 2.4 Ground-State H Atom, 30 2.4.1 Result of Rigorous Treatment (see Chapter 4), 30 2.4.2 Box Model for H Atom and the Variational Principle, 32 2.5 Ground-State H+, 36 2.5.1 Forming H* from an H Atom and a Proton, 36 2.5.2 Box Test Functions for H+, 37 2.6 Conclusion, 40 Reference, 41 3 Schrodinger Equation, 42 3.1 Introduction, 42 3.2 Wave Equation and Schrodinger Equation, 42 3.2.1 Wave Equation, 42 3.2.2 One-Dimensional Schrodinger Equation, 45 3.2.3 Three-Dimensional Schrodinger Equation, 53 3.3 Normalized Wavefunction: p = iff2, 57 3.3.1 One-Dimensional Box Function, 57 3.3.2 Three-Dimensional Box Function, 59 3.4 Orthogonality of the Wavefunctions, 60 3.4.1 Nondegenerate Wavefunctions, 60 3.4.2 Degenerate Wavefunctions, 61 3.4.3 Degeneracy Removed in an Electric Field, 62 3.5 Bohr Correspondence Principle and Generalized Form of Quantum Mechanics, 63 3.5.1 Bohr Correspondence Principle, 64 3.5.2 popif of a Free Electron and Eigenvalue Equations, 65 3.5.3 Electron Moving on a Circle, 66 3.5.4 Degeneracy Removed by Magnetic Field, 68 3.5.5 Operator for Angular Momentum, 68 3.5.6 Operator ihd/dt and the Time-Dependent Schrodinger Equation, 69 3.5.7 Relation Between Time-Independent and Time-Dependent Schrodinger Equations, 70 3.5.8 Average Values of an Observable (also Called Expectation Value), 71 3.5.9 Heisenberg Uncertainty Principle, 71 3.6 Summary of Postulates of Quantum Mechanics, 74 3.7 Conclusion, 75 References, 75 4 Hydrogen Atom, 76 4.1 Introduction, 76 4.2 Hydrogen Atom in the Ground State, 76 4.2.1 Wavefunction, 77 4.2.2 Energy, 78 4.2.3 Radial Probability Distribution of Electron, 79 CONTENTS ix 4.2.4 Most Probable Distance and Average Distance, 80 4.2.5 Average Potential Energy and Virial Theorem, 81 4.3 H Atom in Excited States, 82 4.3.1 Energies, 82 4.3.2 Wavefunctions, 83 4.3.3 Radial Probability Distribution Function and Average Distance, 87 4.3.4 Emission Spectra, 88 4.3.5 Degeneracy of H-atom Orbitals Can Be Removed by a Magnetic Field, 90 4.4 Conclusion, 92 5 Atoms and the Variational Principle, 93 5.1 Introduction, 93 5.2 Vanational Principle, 93 5.2.1 Introducing the Variational Principle, 93 5.2.2 Justification of the Variational Principle, 94 5.3 He Atom, 98 5.3.1 Ground State of He, 98 5.3.2 Indistinguishability of Electrons, 103 5.3.3 Excited States of He Described by the Product of One-Electron Trial Functions (Orbitals), 103 5.4 Electron Spin and Pauli Exclusion Principle, 104 5.4.1 Energy Splitting in a Magnetic Field, Electron Paramagnetic Resonance, 104 5.4.2 Spin Variables, 107 5.4.3 Antisymmetry Postulate (Pauli Exclusion Principle), 109 5.4.4 Singlet-Triplet Splitting: Magnetic Forces Negligible, 111 5.5 Many-Electron Atoms, 112 5.5.1 Atomic Number Z and lonization Energy, 112 5.5.2 Electronic Structure of the First Three Elements, 113 5.5.3 Aufbau Principle and the Periodic Table, 115 5.5.4 Periodic Properties of the Elements, 120 5.6 Spin-Orbit Interactions of Electrons in Atoms, 122 5.6.1 Angular Momentum and Vector Model of Atoms, 123 5.6.2 Atomic Term Symbols, 125 5.7 Conclusion, 127 References, 127 6 A Quantitative View of Chemical Bonding, 128 6.1 Introduction, 128 6.2 H^ Molecular Ion, 129 6.2.1 Electron Described by Exact Wavefunction, 129 6.2.2 Electron Density and the Chemical Bond, 131 6.2.3 Electron Described by the Linear Combination of Atomic Orbitals (LCAO) Wavefunction, 133 x CONTENTS 6.2.4 Comparison of Box Model and LCAO Method, 136 6.2.5 Excited State of H : Bonding and Antibonding Orbitals, 138 6.3 H2: A Two-Electron System, 139 6.3.1 Rigorous Treatment, 139 6.3.2 Product of One-Electron Wavefunctions, 141 6.3.3 Indistinguishability of Electrons, 143 6.3.4 Pauli Exclusion Principle: Electronic Wavefunctions Must Be Antisymmetric, 146 6.4 Tunneling, 148 6.4.1 Electron Oscillating Between Protons a and b, 148 6.4.2 Tunneling Barrier and Frequency of Oscillation, 148 6.4.3 Importance of Tunneling in Redox Chemistry, 148 6.5 Conclusions, 149 References, 149 7 Bonding Described by Electron Pairs and Molecular Orbitals, 150 7.1 Introduction, 150 7.2 Electron Pair Bonds, 150 7.2.1 Connectivity of Atoms in Three-Atom Molecules, 151 7.2.2 Geometries for Electron Pair Bonds, 154 7.2.3 Limitations of the Electron Pair Model, 160 7.3 Molecular Orbitals, 161 7.3.1 Homonuclear Diatomics, 161 7.3.2 Heteronuclear Diatomics, 167 7.3.3 Triatomics (H2O), 170 7.3.4 Polyatomics, 174 7.4 Polarity, Bond length, and Elasticity, 177 7.4.1 Polarity of Bonds and Electronegativity, 177 7.4.2 Covalent Radii and Van der Waals Radii, 179 7.4.3 Stretching, Bending, and Torsion of Bonds, 182 7.5 Conclusions, 188 References, 188 8 Molecules with n-Electron Systems, 189 8.1 Introduction, 189 8.2 Bonding Properties of 7t-Electrons, 190 8.2.1 a -Bonded Molecular Skeleton and tt -Electrons, 190 8.2.2 Overview of Models for it-Systems, 192 8.3 Free Electron Molecular Orbital (FEMO) Model, 194 8.3.1 Ethene, Butadiene, Amidinium 7i-Electron Chains, 194 8.3.2 Benzene: A Tt-Electron Ring, 195 8.3.3 Charge Density dQ/ds, 197 8.3.4 Branched Molecules, 200 8.4 Bondlength Consistent With Total it-Electron Density Method (BCD), 203 8.5 Principles of Density Functional Theory (DFT), 209 8.6 HMO Model, 210 8.6.1 Wavefunctions and Energies, 210 CONTENTS xi 8.6.2 Application of the HMO Method to 7t-Electron Chains, 213 8.6.3 Bond Length and HMO Bond Order, 215 8.7 Resonance, 216 8.8 Conclusions, 218 References, 219 9 Absorption of Light, 220 9.1 Introduction, 220 9.2 Excitation of it-Electron Systems, 220 9.2.1 Basic Experimental Facts, 220 9.2.2 Absorption Maxima of Dyes, 226 9.2.3 Strength and Polarization of Absorption Bands, 231 9.2.4 Hetero-Atoms as Probes for Electron Distribution, 235 9.2.5 HOMO-LUMO Gap by Bond Alternation, 239 9.2.6 Cyclic jr-Systems, 242 9.2.7 Coupling of n-Electrons, 247 9.3 Optical Activity, 249 9.3.1 Rotatory Dispersion, 250 9.3.2 Ellipticity and Circular Dichroism, 251 9.3.3 Anisotropy Factor g for Model in Fig. 9.23, 254 9.3.4 Absolute Configuration of Chiral Molecules, 255 9.3.5 Circular Dichroism of Spirobisanthracene, 255 9.3.6 Circular Dichroism of Chiral Cyanine Dye, 258 9.4 Conclusions, 260 References, 260 10 Emission of Light, 261 10.1 Introduction, 261 10.2 Spontaneous Emission, 261 10.2.1 Fluorescence, 262 10.2.2 Phosphorescence and Triplet States, 267 10.2.3 Relative Energetics of Fluorescence, Phosphorescence, and Absorption, 270 10.2.4 Quenching of Fluorescence, 272 10.2.5 Absorption from Excited States, 273 10.3 Stimulated Emission and Laser Action, 275 10.3.1 Inversion of Population, 276 10.3.2 Dye Laser Operation, 276 10.3.3 Excimer and Exciplex Laser, 279 10.4 Conclusions, 279 References, 279 11 Nuclei: Particle and Wave Properties, 280 11.1 Introduction, 280 11.2 Rotational Motion of Molecules, 281 11.2.1 Diatomic Quantum-Mechanical Rotator, 281 11.2.2 Polyatomic Molecules, 284 11.2.3 Rotational Spectra, 287 xii CONTENTS 11.3 Vibrational Motion of Molecules, 293 11.3.1 Classical Oscillator, 293 11.3.2 Quantum-Mechanical Harmonic Oscillator, 296 11.3.3 Vibrational-Rotational Spectra, 301 11.3.4 Quantum-Mechanical Anharmonic Oscillator, 310 11.4 Raman Spectra, 315 11.4.1 Rayleigh Scattering, 315 11.4.2 Raman Spectroscopy, 317 11.4.3 Rotational Raman Spectra of Heteronuclear Diatomic Molecules, 318 11.4.4 Raman Spectra of Poly atomics, 322 11.5 Vibrational Structure of Electronic Spectra, 324 11.5.1 Franck-Condon Principle, 325 11.5.2 Photoelectron Spectroscopy, 328 11.5.3 Polyatomic Molecules, 331 11.6 Conclusion, 336 References, 336 12 Nuclear Spin, 337 12.1 Introduction, 337 12.2 Nuclear Spin: Fundamentals, 337 12.2.1 Spin of Protons in H2, 337 12.2.2 Antisymmetry of Total Wavefunction of a Molecule Including Electrons and Nuclei, 338 12.2.3 Nuclei With Half-Integer Spin (Antisymmetric Total Wavefunction) and Nuclei With Integral Spin (Symmetric Total Wavefunction), 340 12.3 Nuclear Magnetic Resonance (NMR), 343 12.3.1 Fundamentals, 343 12.3.2 Chemical Shift, 345 12.3.3 Fine Structure of NMR Spectra, 347 12.3.4 NMR Spectroscopy for Determination of Protein Structures in Solution, 349 12.3.5 Magnetic Resonance Imaging (MRI), 350 12.4 Conclusion, 350 References, 350 13 Solids and Intermolecular Forces, 351 13.1 Introduction, 351 13.2 Ionic Crystals, 352 13.2.1 Bond Energy of an Ion Pair, 352 13.2.2 Lattice Types, 354 13.3 Metals, 358 13.3.1 Free Electron Model for Conduction Electrons, 358 13.3.2 Cohesion Energy of Metals, 364 133.3 Quantum Wires and Nanostructure, 366 CONTENTS xlii 13.4 Semiconductors, 369 13.4.1 Soliton Conductors: Polyacetylene, 369 13.4.2 Silicon, 370 13.4.3 Semiconductor Bandgap, 371 13.4.4 Semiconductor Quantum Dots, 372 13.5 Molecular Crystals and Intermolecular Forces, 374 13.5.1 Electrostatic Forces, the Dipole, 375 13.5.2 Hydrogen Bonds, 378 13.5.3 Induction Forces, 381 13.5.4 Dispersion Forces, 383 13.6 Conclusions, 386 References, 386 14 Thermal Motion of Molecules, 387 14.1 Introduction, 387 14.2 Kinetic Gas Theory and Temperature, 387 14.2.1 Thermal Motion and Pressure, 388 14.2.2 Avogadro s Law, 395 14.2.3 Thermal Equilibration and Heat, 397 14.2.4 Ideal Gas Law and the Definition of Absolute Temperature, 397 14.2.5 Law of Partial Pressures, 401 14.3 Speed and Collisions of Gas Molecules, 402 14.3.1 Average Speed of Molecules in a Gas, 402 14.3.2 Mean Free Path and Number of Collisions, 405 14.3.3 Diffusion, 408 14.3.4 Viscosity Arising from Collisions of Molecules, 422 14.4 Thermal Motion in Liquids, 426 14.4.1 Collisions in Liquids, 426 14.4.2 Diffusion Coefficient D of a Liquid, 427 14.4.3 Viscosity of a Liquid, 428 14.4.4 Stokes-Einstein Equation, 429 14.5 Conclusions, 431 References, 431 15 Energy Distribution in Molecular Assemblies, 433 15.1 Introduction, 433 15.2 The Boltzmann Distribution Law, 434 15.2.1 System Consisting of Two Quantum States, 434 15.2.2 Systems Consisting of Many Quantum States, 436 15.2.3 Internal Energy U, 438 15.3 Electronic Energy, 439 15.4 Vibrational Energy, 440 15.4.1 Population Number Nn of a Harmonic Oscillator, 441 15.4.2 Internal Energy Uvn, of Diatomic Molecules, 444 15.4.3 Internal Energy Uvn, of Polyatomic Molecules, 446 xiv CONTENTS 15.5 Rotational Energy, 448 15.5.1 Population Number Nj of Rigid Rotator (Heteronuclear Molecules), 449 15.5.2 Internal Energy UI0t of Rotation (Heteronuclear Molecules), 451 15.5.3 Homonuclear Diatomic Molecules: Ortho- and Para-H2, 453 15.6 Translational Energy, 455 15.6.1 Internal Energy [/trans of Translation According to Quantum Mechanics, 455 15.6.2 Maxwell-Boltzmann Distribution of Speeds, 456 15.7 Characteristic Temperature, 462 15.8 Proving the Boltzmann Distribution for Distinguishable Particles, 463 15.8.1 Distribution of N Particles Among Three Levels with Given Internal Energy, 463 15.8.2 Rigorous Treatment, 468 15.9 Proving the Boltzmann Distribution for Indistinguishable Particles (High Temperature), 469 15.9.1 Number of Available Quantum States, 469 15.9.2 Number of Representations and Boltzmann Law, 470 15.9.3 Calculating the Internal Energy U of an Ideal Atomic Gas, 471 15.9.4 Relation Between 0 and T, 472 15.10 Energy Distribution of Fermions and Bosons Among Quantum States, 472 15.11 Conclusions, 475 Reference, 475 16 Work w, Heat q, and Internal Energy U, 476 16.1 Introduction, 476 16.2 Thermodynamic Systems, 477 16.2.1 Defining System and Surroundings, 477 16.2.2 Defining Thermodynamic States, 477 16.2.3 Change of State, 480 16.3 Change of State at Constant Volume (Isochoric Process), 481 16.3.1 Change of Internal Energy A U and the Heat q, 482 16.3.2 Heat Capacity Cy: Definition, 484 16.3.3 Translational Contribution to Cy of a Gas, 485 16.3.4 Rotational and Vibrational Contributions to Cy of a Gas, 486 16.3.5 Ortho- and Para-Hj: Fascinating Quantum Effects on Cv, 488 16.3.6 Electronic Contribution to Cy (Cy,ei), 489 16.3.7 Heat Capacity and Characteristic Temperature, 490 16.3.8 Cv of Solids, 491 CONTENTS XV 16.4 Change of State at Constant Pressure (Isobaric Process), 494 16.4.1 Change of Internal Energy AU: Heat q and work w, 494 16.4.2 Enthalpy H and Heat Capacity Cp: Definition, 495 16.5 Heat Exchange and Chemical Reactions, 498 16.5.1 Reaction at Constant Volume: AU, 498 16.5.2 Reaction at Constant Pressure: AH, 501 16.5.3 Temperature Dependence of AU and AH, 502 16.5.4 Molar Enthalpies of Formation from Elements AfH°, 505 16.5.5 Molar Enthalpy of Reaction Ar#°, 505 16.5.6 Bond Enthalpies and Bond Energies, 508 16.5.7 Enthalpies and Reaction Cycles, 509 16.6 Conclusions, 510 References, 511 17 Reversible Work w^y, Reversible Heat ^rev, and Entropy S, 512 17.1 Introduction, 512 17.2 Irreversible and Reversible Changes of State, 513 17.2.1 Irreversible Changes, 513 17.2.2 Reversible Changes, 513 17.3 Counting the Number of Representations of a Thermodynamic State, Q, 523 17.3.1 Distribution Possibilities, 523 17.3.2 Number of Representations £2 of an Atomic Gas in a Given Thermodynamic State, 526 17.4 The Entropy: S = k In ft, 529 17.4.1 Entropy of Subsystems, 529 17.4.2 Entropy of Atomic Gas: Sackur-Tetrode Equation, 530 17.5 Entropy Change AS, 533 17.5.1 Temperature Equilibration: Entropy Increase, 534 17.5.2 Mixing: Entropy Increase, 536 17.5.3 Entropy Cannot Decrease for an Isolated System, 537 17.5.4 Entropy Can Decrease in Closed Systems, 537 17.6 Heat and Entropy Change, 537 17.6.1 Heat and Entropy Change for an Ideal Gas, 538 17.6.2 Cyclic Processes (AS — 0) and Processes in Isolated Systems (AS 0), 542 17.6.3 Heat and Entropy Change in Arbitrary Processes, 542 17.7 Thermodynamic Temperature Scale and Cooling, 543 17.7.1 Thermodynamic Temperature Scale, 543 17.7.2 How Low Can Temperature Go?, 547 17.8 Entropies of Substances, 547 17.8.1 Entropy of an Atomic Gas, 550 17.8.2 Entropy of Diatomic Gases, 553 17.8.3 Entropy of Polyatomic Gases, 555 17.8.4 Entropy of Different Substances, 557 xvi CONTENTS 17.9 Laws of Thermodynamics, 559 17.10 Conclusions, 561 References, 561 18 General Conditions for Spontaneity and its Application to Equilibria of Ideal Gases and Dilute Solutions, 562 18.1 Introduction, 562 18.2 General Conditions for Spontaneity, 563 18.2.1 Helmholtz Energy A, 565 18.2.2 Gibbs Energy G, 566 18.3 AG and its Dependence on Temperature, 567 18.3.1 Molar Gibbs Energy of Formation from Elements AfG°, 567 18.3.2 Molar Gibbs Energy of Reaction ArG°, 567 18.3.3 Temperature Dependence of AG°, 568 18.4 Pressure Dependence of AG in Ideal Gases, 570 18.4.1 Vapor Pressure (Clausius-Clapeyron Equation), 572 18.4.2 Chemical Evolution of a Gas, 574 18.5 AG and Chemical Equilibrium in Ideal Gases, 575 18.5.1 Formal Derivation of Mass Action Law, 575 18.5.2 Mass Action Law: A Direct Consequence of the Relation Between Work and Heat, 578 18.5.3 Applying the Mass Action Law, 581 18.5.4 Temperature Dependence of Equilibrium Constant K, 584 18.5.5 Pressure Changes and Equilibrium, 588 18.5.6 Reactions Involving Gases and Immiscible Condensed Species, 589 18.5.7 Equilibrium Constant from Molecular Properties, 590 18.6 AG and Equilibrium in Dilute Solution, 593 18.6.1 Osmotic Pressure and Concentration, 593 18.6.2 Depression of Vapor Pressure (Raoult s law), 596 18.6.3 Elevation of Boiling Point and Depression of Melting Point, 600 18.6.4 Mass Action Law (Solutions of Neutral Particles), 602 18.6.5 Mass Action Law (Solutions of Charged Particles), 604 18.6.6 Gibbs Energy of Formation in Aqueous Solution, 604 18.6.7 Part of Reactants or Products in Condensed or Gaseous State, 607 18.7 Conclusions, 608 References, 608 19 Formal Thermodynamics and its Application to Phase Equilibria, 609 19.1 Introduction, 609 19.2 Internal Energy, Enthalpy, Work, and Heat, 609 19.2.1 Work, 610 19.2.2 Heat, 611 CONTENTS xvii 19.2.3 Relating U and H to Measurable Quantities, 612 19.2.4 Maxwell Relations, 615 19.2.5 An Important Application: Calculating Cp — Cy, 615 19.3 Spontaneity and Free Energy, 617 19.3.1 Helmholtz Energy A, 618 19.3.2 Gibbs Energy G, 619 19.4 Phase Equilibria and Phase Transitions, 620 19.4.1 Solid-Liquid Equilibria, 622 19.4.2 Liquid-Gas and Solid-Gas Equilibria, 624 19.4.3 Phase Diagrams and Phase Rule, 626 19.5 Conclusions, 630 References, 630 20 Real Gases, 631 20.1 Introduction, 631 20.2 AG for Real Gases and the Fugacity, 631 20.3 Equations of State for Real Gases, 634 20.3.1 Hard Sphere Gas, 634 20.3.2 Van der Waals Equation, 637 20.3.3 Critical Point and Van der Waals Constants, 638 20.3.4 Virial Equation of State, 641 20.4 Change of State of Real Gases, 644 20.4.1 Adiabatic Expansion into Vacuum, 644 20.4.2 Joule-Thomson Effect, 646 20.5 Chemical Equilibria Involving Real Gases, 649 20.6 Conclusions, 651 References, 651 21 Real Solutions, 652 21.1 Introduction, 652 21.2 Partial Molar Quantities and Thermodynamics of Multicomponent Systems, 652 21.2.1 Partial Molar Volume, 653 21.2.2 Chemical Potential, 654 21.2.3 Thermodynamic Relations, 655 21.3 Activities and Activity Coefficient for Real Solutions, 657 21.3.1 Activity from Vapor Pressure Above a Solution, 657 21.3.2 Activity from Osmotic Pressure, 659 21.4 Phase Transitions of Solutions, 661 21.4.1 Elevation of Boiling Point and Depression of Melting Point, 661 21.4.2 Solutions with Two Volatile Components, 663 21.5 Mass Action Law For Reactions in Solution, 665 21.6 Electrolyte Solutions and the Debye-Hiickel Theory, 667 21.6.1 Debye-Hiickel Theory for Electrolytes, 667 21.7 Conclusions, 671 References, 671 xviii CONTENTS 22 Reaction Equilibria in Aqueous Solutions and Biosystems, 672 22.1 Introduction, 672 22.2 Proton Transfer Reactions: Dissociation of Weak Acids, 673 22.2.1 Henderson-Hasselbalch Equation, 673 22.2.2 Degree of Dissociation in Aqueous Solution, 675 22.2.3 Degree of Dissociation in a Buffer Solution, 676 22.2.4 Titration Curve of a Weak Acid, 677 22.3 Stepwise Proton Transfer, 678 22.3.1 Diprotic Acid, 678 22.3.2 Amino Acids, 681 22.4 Electron Transfer Reactions, 682 22.4.1 Electron Transfer from Metal to Proton: Dissolution of Metals in Acid, 682 22.4.2 Electron Transfer from Metal 1 to Metal 2 Ion: Coupled Redox Reactions, 684 22.4.3 Electron Transfer to Proton at pH 7: AG° , 685 22.4.4 Photoinduced Electron Transfer, 686 22.5 Electron Transfer Coupled with Proton Transfer, 688 22.6 Group Transfer Reactions in Biochemistry, 691 22.6.1 Group Transfer Potential, 692 22.6.2 Coupled Reactions in Biology, 692 22.7 Bioenergetics, 693 22.7.1 Synthesis of Glucose, 694 22.7.2 Combustion of Glucose, 695 22.7.3 Energy Balance of Formation and Degradation (Combustion) of Glucose, 695 22.8 Conclusions, 696 References, 696 23 Chemical Reactions in Electrochemical Cells, 697 23.1 Introduction, 697 23.2 AG and Potential E of an Electrochemical Cell, 697 23.3 Simple Cells and Nernst Equation, 701 23.3.1 Metal/Metal Ions, 701 23.3.2 Gas Electrodes, 704 23.3.3 Nernst Equation and Standard Potential, 705 23.4 Standard Potential £° and Reference Electrodes, 707 23.4.1 Practical Determination of £°, 708 23.4.2 Absolute Electrode Potential, 709 23.5 Use of Electrochemical Cells for Thermodynamic Measurements, 714 23.5.1 pH Electrodes, 714 23.5.2 Measurement of Mean Activity Coefficient y±, 716 23.53 Measurement of Equilibrium Constant, 718 23.5.4 Liquid-Liquid Junctions, 719 23.6 Applications of Electrochemical Cells, 721 23.6.1 Galvanic Cells: Batteries and Accumulators, 721 CONTENTS Xix 23.6.2 Fuel Cells, 724 23.6.3 Electrolysis and Electrosynthesis, 725 23.6.4 Overvoltage, 727 23.7 Conductivity of Electrolyte Solutions, 728 23.7.1 Mobility of Ions, 728 23.7.2 Generalization, 730 23.7.3 Mobility of H+, 731 23.7.4 Ion Transport through Membranes, 732 23.8 Conclusions, 733 References, 733 24 Chemical Kinetics, 735 24.1 Introduction, 735 24.2 Collision Theory for Gas Reactions, 736 24.2.1 Counting the Number of Collisions, 736 24.2.2 Activation, 737 24.2.3 Steric Factor, 740 24.3 Rate Equation for Elementary Bimolecular Reactions, 740 24.3.1 Rate Constant and Frequency Factor for a Gas-Phase Reaction, 740 24.3.2 Rate Constant and Frequency Factor for a Reaction in Solution, 745 24.4 Rate Laws, 748 24.4.1 What is a Rate Law?, 749 24.4.2 Zero-Order Rate Law, 749 24.4.3 First-Order Rate Law, 750 24.4.4 Second-Order Rate Law, 752 24.5 Activation Energy and Frequency Factor, 755 24.5.1 Arrhenius Plot, 755 24.5.2 The Chemist s Rule of Thumb, 756 24.6 Combinations of Elementary Reactions, 756 24.6.1 Reactions Leading to Equilibrium, 756 24.6.2 Parallel Reactions, 759 24.6.3 Consecutive Reactions, 760 24.7 Complex Reactions, 761 24.7.1 Approximation Methods, 761 24.7.2 Lindemann-Hinshelwood Mechanism, 764 24.7.3 Chain Reactions, 767 24.7.4 Enzyme Reactions (Michaelis-Menten Mechanism), 769 24.7.5 Autocatalytic Reactions, 772 24.7.6 Bistability, 778 24.7.7 Oscillating Reactions, 780 24.7.8 Chemical Waves, 784 24.8 Experimental Methods, 786 24.8.1 Monitor Reaction Progress and Sampling, 786 24.8.2 How Methods, 787 24.8.3 Quenching Methods, 788 xx CONTENTS 24.8.4 Flash Photolysis, 789 24.8.5 Relaxation Method, 791 24.9 Conclusions, 794 References, 794 25 Transition States and Chemical Reactions, 795 25.1 Introduction, 795 25.2 Transition State in a Statistical View, 795 25.2.1 Transition State Theory for Bimolecular Reactions, 796 25.2.2 Transition State Theory for Unimolecular Reactions, 806 25.2.3 Applications of Transition State Theory, 808 25.3 Transition State in a Dynamical View, 813 25.3.1 State to State Reaction Rates, 813 25.3.2 Transition State Spectroscopy, 816 25.3.3 Rate Constant kt(E) from Reaction Cross-Sections, 817 25.3.4 Relation Between kT(E) and the Rate Constant kt(T), 819 25.4 Transition State Theory and Reactions in Solution, 820 25.4.1 Unimolecular Reactions and Frictional Coupling, 821 25.4.2 Dissociation Reactions, 823 25.4.3 Proton Transfer Reactions, 826 25.5 Conclusions, 827 References, 828 26 Macromolecules, 829 26.1 Introduction, 829 26.2 Random Coil, 829 26.2.1 A Chain of Statistical Chain Elements, 831 26.3 Measuring the Length of Statistical Chain Elements, 835 26.3.1 Light Scattering, 835 26.3.2 Hydrodynamics: Coil Approximated as a Sphere, 839 26.3.3 Hydrodynamics: Macroscopic Modeling, 842 26.4 Uncoiling a Coil and its Recoiling, 848 26.4.1 Unraveling Coil by Force Applied at Chain Ends, 848 26.4.2 Fully Unraveling a Coil in a Flowing Medium, 852 26.4.3 Partially Unraveling a Coil in a Flowing Medium, 854 26.4.4 Restoring Coil, 857 26.5 Proteins as Biopolymers, 859 26.6 Motion Through Entangled Polymer Chains, 861 26.6.1 Moving Random Coil by Winding Through Meshwork: Gel Electrophoresis of DNA Fragments, 863 26.7 Rubber Elasticity, 865 26.8 Conclusion, 867 References, 867 27 Organized Molecular Assemblies, 869 27.1 Introduction, 869 27.2 Liquid Surfaces and Liquid/Liquid Interfaces, 869 27.2.1 Surface Tension and Interfacial Tension, 869 CONTENTS XXJ 27.2.2 Surface Active Molecules (Surfactants), 874 27.3 Films on Solid Surfaces, 880 27.3.1 Langmuir-Blodgett Films (LB Films), 880 27.3.2 Self-Assembled Monolayers (SAM), 881 27.3.3 Contact Angle, 882 27.4 Micelles, 883 27.4.1 Spherical Micelles: Critical Micelle Concentration, 885 27.4.2 Geometry of Packing, 891 27.5 Membranes, 892 27.5.1 Liposomes, 892 27.5.2 Soap lamella, 893 27.5.3 Black lipid membranes, 894 27.6 Biomembranes, 896 27.6.1 Lateral Diffusion, 896 27.6.2 Ion Transport Through a Membrane, 896 27.6.3 Transport of Small Protein Through a Membrane, 899 27.7 Liquid Crystals, 900 27.7.1 Optics Applications of Liquid Crystals, 902 27.8 Conclusions, 906 References, 906 28 Supramolecular Machines, 908 28.1 Introduction, 908 28.2 Idea of a Supramolecular Machine, 909 28.2.1 A Simple Energy Transduction Device, 909 28.2.2 Programmed Interlocking Molecules, 910 28.3 Manipulating Photon Motion, 913 28.3.1 Energy Transfer Between Dye Molecules: FRET, Ruler in Nanometer Range; SNOM, 913 28.3.2 Functional Unit by Coupling Chromophores, 920 28.3.3 Dye Aggregate as Energy-Harvesting Device, 921 28.3.4 Solar Energy Harvesting in Biosystems, 926 28.3.5 Manipulating Luminescence Lifetime by Programming Echo Radiation Field, 927 28.4 Manipulating Electron Motion, 930 28.4.1 Photoinduced Electron Transfer in Designed Monolayer Assemblies, 930 28.4.2 Tunneling Current Through Monolayers, 932 28.4.3 Conduction Through Single Molecules, 935 28.4.4 Conjugated Molecular Tethers, 940 28.4.5 Electron Transfer in Proteins, 941 28.4.6 Solar Energy Conversion: The Electron Pump of Plants and Bacteria, 943 28.4.7 Electron Transfer in Soft Medium, 947 28.4.8 Inverted Region of Electron Transfer Reactions, 949 28.4.9 Artificial Photoinduced Electron Pumping, 951 28.5 Manipulating Nuclear Motion, 952 28.5.1 Light-Induced Change of Monolayer Properties, 952 xxii CONTENTS 28.5.2 Mechanical Switching Devices, 954 28.5.3 Photoinduced Sequence of Amplification Steps: The Visual System, 955 28.5.4 Solar Energy Conversion in Halobacteria, 956 28.5.5 Biomotors, 961 28.6 Conclusions, 969 References, 969 29 Origin of Life: Matter Carrying Information, 973 29.1 Introduction, 973 29.2 Investigation of Complex Systems, 974 29.2.1 Need for Simplifying Models, 974 29.2.2 Increasing Simplification with Increasing Stages of Complexity, 974 29.3 Can Life Emerge by Physicochemical Processes?, 974 29.3.1 Bioevolution as a Process of Learning How to Survive as a Species, 974 29.3.2 Model Case for the Learning Mechanism, 975 29.4 Modeling the Emergence of the Genetic Apparatus, 977 29.4.1 Basic Questions, 977 29.4.2 Evolution of the Universe and Evolution of Life: The Big Bang and the Tiny Bang, 980 29.4.3 Paradigm of Present Attempt to Understand the Origin of Life, 980 29.4.4 General Conditions for Life to Come into Being: Periodicity in Time, Compartmentalization, and Structural Diversity, 981 29.4.5 Definition of Life in the Present Context, 982 29.4.6 Modelling a Continuous Sequence of Physicochemical Processes Leading to a Genetic Apparatus, 982 29.5 General Aspects of Life s Emergence and Evolution, 986 29.5.1 Information and Knowledge, 986 29.5.2 Processing Information, Genesis of Information and Knowledge, and the Maxwell Demon, 986 29.5.3 Limits of Physicochemical Ways of Thinking, 990 29.6 Conclusions, 993 References, 993 Index, 995 List of Foundations 1 Chapter 1 2 Chapter 2 3 Chapter 3 3.1 Electron in a Potential Well of Finite Depth 3.1.1 Symmetric Solutions 3.1.2 Antisymmetric Solutions 3.1.3 Numerical Evaluation 3.2 Orthogonality 3.3 Uncertainty Principle 3.3.1 Uncertainty in the Momentum 3.3.2 Uncertainty in the Position 3.3.3 Uncertainty Product 3.3.4 Example: Gaussian Distribution of Momenta 4 Chapter 4 4.1 H Atom: Solution of the Schrodinger Equation 4.2 H Atom: Angular and Radial Wavefunctions 4.2.1 The Angular Solution 4.2.2 The Radial Solution 4.2.3 The Total Wavefunction 5 Chapter 5 5.1 Proof of Variational Principle 5.2 First Order Perturbation Theory 5.2.1 Example: Electron in a Potential Well 5.3 Perturbation Theory (Rigorous Treatment) 5.3.1 Example: Electron in a Potential Well 5.4 He-Atom: Repulsion Energy 5.5 The Self-Consistent Field approximation 5.6 Atomic Term Symbols 6 Chapter 6 6.1 H^ Ion: Exact Wavefunction and Energy 6.1.1 Energy 6.1.2 Wavefunction for the Equilibrium Distance 6.1.3 Virial Theorem for Molecules 6.2 Evaluation of LCAO Integrals in H^ 6.3 Oscillation of Electron between Protons at Distance d (Tunneling) 6.3.1 Calculating E and £2 in H^ for Large Distance d 6.3.2 Calculating £2 — £1 6.3.3 Calculating the Time-Dependent Probability Density p 6.3.4 Period of Oscillation 6.3.5 Tunneling Probability xxiii xxiv LIST OF FOUNDATIONS 7 Chapter 7 7.1 LCAO-Treatment of Heteronuclear Diatomic Molecules 8 Chapter 8 8.1 Construction of V(s) in Figure 8.3 8.2 Free-Electron Model 8.2.1 Case 1: Symmetric Wavefunctions 8.2.2 Case 2: Antisymmetric Wavefunctions 8.2.3 Energies 8.2.4 Normalization 8.3 Free-Electron Model, Representation by Determinants 8.4 HMO Model 8.4.1 Finding the Minimum of e 8.4.2 Solving a system of N linear equations with constant coefficients 8.4.3 Example: butadiene 8.4.4 Example: benzene 8.5 Fullerene 9 Chapter 9 9.1 Integrated Absorption: Classical Oscillator 9.1.1 Absorbed Power in a Radiation Beam and Absorption Coefficient e 9.1.2 Calculating the Absorption Coefficient e Classically 9.1.3 Resonance Curve for e: Calculating Jband £ • du 9.1.4 Integrated Absorption Power 9.1.5 Derivation of Equation (9.4) for the Intensity / 9.2 Oscillator Strength: Quantum Mechanical Treatment 9.2.1 Quantum Mechanical Expression for / 9.3 Classical and Quantum Mechanical Description of Light Absorption 9.3.1 Light Absorption Calculated from the Schrodinger Equation 9.3.2 Power Absorbed by the Molecule 9.3.3 Classical Oscillator 9.3.4 Equivalence of Classical and Quantum Mechanical Treatment 9.4 Coupling Transitions with Parallel Transition Moments 9.4.1 Replacing Quantum Mechanical System by Coupled Classical Oscillators 9.4.2 Doubly Occupied Orbitals 9.5 Normal Modes of Coupled Oscillators 9.5.1 Resonance Frequencies of Two Coupled Oscillators 9.5.2 Oscillator Strength of Two Coupled Oscillators 9.5.3 Coupling Two Identical Oscillators 10 Chapter 10 10.1 Fluorescence Life Time 10.1.1 Antenna Equation of Hertz 10.1.2 Natural Lifetime 10.1.3 Lifetime and Line Width LIST OF FOUNDATIONS xxv 10.2 Calculation of Repulsion Integrals 10.2.1 Deriving Equations for the Integrals 10.2.2 Numerical Integration 11 Chapter 11 11.1 Rotator: Solution of the Schrodinger Equation 11.1.1 Diatomics 11.1.2 Polyatomics 11.2 Quantum-Mechanical Treatment of the Harmonic Oscillator 11.2.1 Diatomics 11.2.2 Symmetric wavefunctions 11.2.3 Antisymmetric wavefunctions 11.3 Selection Rules for Rotation of Linear Molecules (Absorption Spectra) 11.3.1 Transition Moment 11.3.2 Intensity Distribution of Absorption Lines 11.4 Centrifugal Effect on Energy of Diatomic Rotator 11.5 Selection Rules for Vibration (Absorption Spectra) 11.5.1 Diatomic Molecules 11.5.2 Polyatomic Molecules 11.6 Selection Rules for Rotation of Linear Molecules (Raman Spectra) 11.6.1 Transition Moment 11.6.2 Intensity of Raman Lines 11.7 Selection Rules for Vibration of Diatomic Molecules (Raman Spectra) 12 Chapter 12 13 Chapter 13 13.1 Some Features of Crystal Structures and Lattices 13.2 Polarizability of a Conducting Sphere 14 Chapter 14 14.1 The Random Walk in Three Dimensions 14.2 Intermolecular Forces Affecting the Mean Free Path 14.3 Law of Hagen-Poiseuille 14.3.1 Flow in a Tube 14.3.2 Volume V of a Gas Flowing Through the Tube 14.3.3 Law of Hagen-Poiseuille for Liquids 15 Chapter 15 15.1 Classical Derivation of the One-Dimensional Maxwell-Boltzmann Distribution of Speeds 15.1.1 Calculation of Constant A 15.2 How to Find the Maximum of In a 15.3 Energy Distribution of Fermions and Boson 15.3.1 Fermions 15.3.2 Bosons 15.3.3 Classical Case ( boltzons ) 15.3.4 Distribution Functions 15.4 Canonical and Microcanonical Ensembles 15.5 Internal Energy U as Sum of Contributions Uei, Uvn,, Urot, and U trans xxvi LIST OF FOUNDATIONS 16 Chapter 16 16.1 Deriving the Debye Function (Cy of Solids) 16.2 How to Calculate f£ ACfm ¦ AT 16.2.1 Hydrogen and Oxygen Gas Reaction, Temperature Range 298 K to 350 K 16.2.2 Hydrogen and Oxygen Gas Reaction, Temperature Range 298 K to 1500 K 16.2.3 Heating Limestone 17 Chapter 17 17.1 Number of Representations Q from Molecular Partition Function Z 17.1.1 Distinguishable Particles 17.1.2 Indistinguishable Particles 17.2 Entropy of Homonuclear Diatomic Gases 18 Chapter 18 18.1 How to Calculate AGt2 from AGTl 18.2 Relationship between the Molecular Partition Function and the Equilibrium Constant 18.3 Isotope Exchange Equilibrium 18.4 How to Determine A G° for Ions 19 Chapter 19 19.1 Some Formal Thermodynamic Relationships 19.1.1 First Order Relations (Maxwell Relations) 19.1.2 Combinations of First Order Relations 19.1.3 Second Order Relations 19.1.4 Change of Variables 19.1.5 Evaluation of Thermodynamic Functions by Measurable Quantities 19.2 Molecular Perspective on Solid-Gas Equilibria 19.2.1 Solid Argon 19.2.2 Solid-Gas Equilibrium for Argon 19.2.3 Thermodynamics of Solids 19.3 Distinguishing Between Phases 20 Chapter 20 20.1 Virial Equation of State 20.1.1 Classical Partition Function 20.2 Joule-Thomson Coefficient and Inversion Temperature 21 Chapter 21 21.1 Activity Coefficient of Solute From Activity Coefficient of Solvent 21.2 Distribution of Ions in Solution 21.2.1 Charge Distribution between Two Plates 21.2.2 Charge Distribution Around an Ion 21.2.3 Poisson Equation 22 Chapter 22 22.1 Titration of Acetic Acid by NaOH 22.1.1 Effect of Increasing Volume 22.2 Two Coupled Chemical Equilibria LIST OF FOUNDATIONS xxvii 22.2.1 Evaluation of concentrations q/2a Om- ar d ca2~ 22.2.2 Titration curve 23 Chapter 23 24 Chapter 24 25 Chapter 25 25.1 Thermal Rate Constants 25.2 Derivation of the Kramers formula 26 Chapter 26 26.1 Light Scattering of Macromolecules 26.1.1 Polarizability a of Macromolecules in the Field of an Incident Light Wave 26.1.2 Forward and Backward Light Scattering 26.2 Viscosity of Dilute Solutions of Polymers and Macroscopic Models 26.2.1 The Dumbbell Model 26.2.2 Viscosity of a Dilute Solution of Dumbbells 26.2.3 Dumbbells and Rotational Form Factor Crot 26.2.4 Conclusion on Viscosity of Dilute Solutions of Random Coils 26.3 Diffusion of a Random Coil in a Gel in the Absence of an Electric Field and Force-Induced Motion 26.3.1 Time r to Leave the Cage. Diffusion Coefficient Di 26.3.2 Global Diffusion of Coil. Diffusion Coefficient D 26.3.3 Force-Induced Motion of Coil 26.4 Stretching a Chain 27 Chapter 27 21.1 Head-to-Head Repulsion Energy 27.2 Clausius-Mosotti Equation 27.2.1 Permanent Dipoles in Electric Field (Simplified Model) 27.2.2 Permanent Dipoles in Electric Field (Rigorous Calculation) 27.2.3 Field Strength in a Liquid 28 Chapter 28 28.1 Energy Transfer 28.1.1 One Donor and One Acceptor in Distance r 28.1.2 Molecules in a Layer Plane 28.1.3 Relation Between r$ and do 28.1.4 Comparison of Absorbed Power in Far Field and Near Field 28.2 Energy Transfer from Exciton to Acceptor 28.2.1 Case (a): Arrangement in Figure 28.14a 28.2.2 Case (b): Arrangement in Figure 28.14b 28.3 Radiation Echo Field 28.3.1 Excited Dye Molecule Without Mirror 28.3.2 Excited Dye Molecule in the Field F of a Mirror 28.3.3 Note 1: Lifetime of Oscillator 28.3.4 Note 2: Conversion of the Hertz Equation 28.4 Electron Transfer Between Tt-Electron Systems xxviii LIST OF FOUNDATIONS 28.4.1 General Case 28.4.2 Rate of Electron Transfer 28.4.3 Evaluation of s 28.4.4 Evaluation of eeiectroniC 28.4.5 Evaluation of Rate Constant kr 28.5 Calculation of Ebarrier 28.6 Marcus Equation 28.7 Chloride Ion Pump and Sensory Receptor of Halobacteria 28.7.1 Chloride Ion Pump 28.7.2 Sensory Receptors 29 Chapter 29 29.1 Search for Logical Conditions Driving the Emergence of a Genetic Translation Device 29.2 The Emergence of a Simple Genetic Apparatus Viewed as a Supramolecular Engineering Problem. A Thought Experiment 29.2.1 A Short Template Marks the Beginning 29.2.2 Intricate Cycles of Temperature Drive Replication 29.2.3 Strand Evolution Requires Rare Replication Errors 29.2.4 Strand Lengthening-Colonization of Larger Porous Regions 29.2.5 Strand Folding: Hairpins-Most Resistant Structure 29.2.6 Aggregation of Hairpins: an Error Filter 29.2.7 Assembler Strand Guides Hairpin Aggregation 29.2.8 A New Variety (a-Monomers) Appears: a-Oligomers Formed by HA Device Enable Colonization of Larger Porous Regions 29.2.9 Breakthrough of Translational Device 29.2.10 Breakthrough of an Integrative Translation Device 29.2.11 Computer Simulation of Thought Experiment 29.3 Attempts to Model the Origin of Life 29.3.1 The Earliest Phase 29.3.2 Breaking Symmetry: Chirality of Nucleotides and Its Evolutionary Benefit 29.3.3 The Earliest HA-Device 29.3.4 The Reading Frame Requirement 29.3.5 Stage-by-Stage Evolution of the Code 29.4 Maxwell s Demon 29.5 Later Evolutionary Steps: Emergence of an Eye With Lens List of Justifications 1 Chapter 1 1.1 Diffraction on a Double Slit 2 Chapter 2 2.1 Mean Distance 7 2.2 Mean Potential Energy V 2.3 Particle in a Box Trial Function for H Atom 3 Chapter 3 3.1 Energy and Momentum of Free Electron 3.2 Energy and Momentum 4 Chapter 4 4.1 Bohr Radius 4.2 Laplace Operator for the H Atom 4.3 Probability in the 2s State of the H Atom 4.4 Calculation of Average Distance 7 for the 2pz state of the H Atom 5 Chapter 5 5.1 Ground State Energy of H Atom by Variational Principle 5.2 Ground State Energy of He+ 6 Chapter 6 6.1 Normalization Constant in Hj Wavefunction 6.2 Excited State of H+ 6.3 Hamiltonian of the H2 Molecule Compared to the Hamiltonians of Two H^ Ions 7 Chapter 7 7.1 Orthogonal Set of Hybrid Functions 7.2 Tetrahedral Hybrid Function 7.3 Stretching Force Constant of H^ Ion 7.4 Morse Function 7.4.1 Limit of Small Elongations 7.4.2 Inflection Point 7.4.3 Maximum Force 8 Chapter 8 8.1 Energies of Benzene for n — 3 8.2 Resonance of Hiickel (An + 2) Rings 8.3 HMO Model: Excited State of Ethene 9 Chapter 9 9.1 Interaction of Electron with Electric and Magnetic Field 9.2 Field Strength in a Molecule Compared to Field Strength of Light Wave 9.3 Energy Shift in Azacyanines 9.4 Shift of Energy Levels by Bond Alternation 9.5 Transition Moment Mx for Phthalocyanine xxix xxx LIST OF J USTIFICAT1ONS 9.6 Light Absorption of Porphynn 9.7 Amsotropy Factor g in Section 9.3.3 9.7.1 Proof of Relation (9.15) 10 Chapter 10 10.1 Singlet-Triplet Transition 10.2 Non-Existence of He2 11 Chapter 11 11.1 Nonrigid Rotator 11.2 Oscillator: Box Wavefunctions 11.3 Classical Oscillator: Probability Density p(x) 11.4 Rotational-Vibrational Spectra: Spacing of Absorption Lines 12 ChapterU 12.1 Raman Spectrum of N2 12.2 Spacing of Raman Lines in O2 and CO2 13 Chapter 13 13.1 Cohesion Energy in Li Metal 13.2 Dipole and Induction Energies 13.2.1 Dipole Energy (Dipoles in Line) 13.2.2 Dipole Energy (Dipoles parallel) 13.2.3 Dipole Energy (Dipoles in Angle /J) 13.2.4 Dipole in the Field of a Point Charge 13.2.5 Electric Field Strength of Dipole 13.3 Polarizability of a Conducting Plate and of a Conducting Sphere 14 Chapter 14 14.1 Collision of Heavy Particle with Light Particle 15 Chapter 15 15.1 Rotational Energy of Symmetric Top Molecules 15.2 Molecular Partition Function Ztmns of Translation 15.3 Calculation of Normalization Constant 15.4 Constant in the Maxwell-Boltzmann Distribution 15.5 Mean Speed 15.6 Occupation Probability in Lowest Quantum State 15.7 Distinguishable Particles Occupying Degenerate Energy levels 16 Chapter 16 16.1 Heat Capacity: Electronic Contribution 16.2 Limits of Debye Function of Heat Capacity 17 Chapter 17 17.1 Temperature Scale 18 Chapter 18 18.1 Equilibrium Constant of H2 + D2 ^ 2HD Equilibrium 18.2 Depression of Melting point 19 Chapter 19 19.1 Derivation of Equation for (dH/dP)T 19.2 More Precise Calculation of AHtotai m 193 Calculation of Vapor Pressure 20 Chapter 20 20.1 Definition of Ideal Gas LIST OF JUSTIFICATIONS xxxi 21 Chapter 21 21.1 Maxwell Relations 21.1.1 Derivation of Equation 21.21 21.1.2 Derivation of Equation 21.22 21.1.3 Derivation of Equation 21.23 21.2 Chemical Potential of Ideal Solution 21.3 Activity Coefficient of Solute from Activity Coefficient of Solvent 21.4 Boiling Point: Approximation for Small Temperature Difference 21.5 Depression of Freezing Point 22 Chapter 22 22.1 pH Change in Buffer Solutions 22.2 pH of Amino Acids 23 Chapter 23 23.1 Thermodynamic and Electrochemical Data 23.2 Gas Electrodes With Different Hydrogen Gas Pressures 24 Chapter 24 24.1 General Form of Second Order Reaction 24.2 Reactions Leading to Equilibrium 24.3 Different Reaction Orders in Both Reactions 24.4 Consecutive Reaction 24.5 Maximum Concentration of Intermediate 24.6 Consecutive Reaction: Special Case k 2 = £ , 24.7 Autocatalytic Reaction 25 Chapter 25 25.1 Reduced Mass of Activated Complex 25.2 Isotope Effect on Reaction Rates 26 Chapter 26 26.1 Light Scattering: Backward Scattering 26.2 Light Scattering: Ratio /i35=//45° 26.3 Force Acting on Chain Ends 27 Chapter 27 21.1 Contact Angles in Figure 27.4 28 Chapter 28 28.1 Circular Dichroism and Structural Features of Chlorosomes 28.2 Electron Transfer: Tunneling Versus Thermal Activation 28.3 Proton Pump: Field of Charged Amino Acids at Chromophore
adam_txt	Titel: Principles of physical chemistry Autor: Kuhn, Hans Jahr: 2009 Contents List of Foundations, xxiii List of Justifications, xxix Preface, xxxiii Acknowledgments, xxxv Authors Biography, xxxvii List of Symbols, xxxix Introduction, 1 1 Wave-Particle Duality, 3 1.1 Overview of Quantum Mechanics, 3 1.1.1 Historical Highlights, 3 1.1.2 An Approach to Quantum Mechanics, 4 1.2 Light, 5 1.2.1 Particle Nature of Light: Photoelectric Effect, 6 1.2.2 Wave Nature of Light: Diffraction, 7 1.2.3 Interpretation of the Experiments, 12 1.3 Electrons, 12 1.3.1 Particle Nature of Electrons, 13 1.3.2 Wave Nature of Electrons, 13 1.3.3 Interpretation of the Experiments, 15 1.3.4 Formal Similarity Between Electron and Photon, 16 1.4 Questions Arising about Wave-Particle Duality, 16 1.4.1 Single Event—Probability Statement; Collective Behavior—Definite Statement, 16 1.4.2 Wave-Particle Duality and the Need to Abandon Familiär Ways of Thinking, 18 1.5 Conclusion, 20 2 Essential Aspects ofStructure and Bonding, 21 2.1 Introduction, 21 2.2 Distinct Energy States, 22 2.2.1 Atomic Spectra, 22 2.2.2 Franck-Hertz Experiment, 23 2.3 Standing Waves, 24 2.3.1 Particle Between Parallel Walls, 25 2.3.2 Ill-Posed Questions, 29 233 Electron in a Cubic Box, 29 vii viii CONTENTS 2.4 Ground-State H Atom, 30 2.4.1 Result of Rigorous Treatment (see Chapter 4), 30 2.4.2 Box Model for H Atom and the Variational Principle, 32 2.5 Ground-State H+, 36 2.5.1 Forming H* from an H Atom and a Proton, 36 2.5.2 Box Test Functions for H+, 37 2.6 Conclusion, 40 Reference, 41 3 Schrodinger Equation, 42 3.1 Introduction, 42 3.2 Wave Equation and Schrodinger Equation, 42 3.2.1 Wave Equation, 42 3.2.2 One-Dimensional Schrodinger Equation, 45 3.2.3 Three-Dimensional Schrodinger Equation, 53 3.3 Normalized Wavefunction: p = iff2, 57 3.3.1 One-Dimensional Box Function, 57 3.3.2 Three-Dimensional Box Function, 59 3.4 Orthogonality of the Wavefunctions, 60 3.4.1 Nondegenerate Wavefunctions, 60 3.4.2 Degenerate Wavefunctions, 61 3.4.3 Degeneracy Removed in an Electric Field, 62 3.5 Bohr Correspondence Principle and Generalized Form of Quantum Mechanics, 63 3.5.1 Bohr Correspondence Principle, 64 3.5.2 popif of a Free Electron and Eigenvalue Equations, 65 3.5.3 Electron Moving on a Circle, 66 3.5.4 Degeneracy Removed by Magnetic Field, 68 3.5.5 Operator for Angular Momentum, 68 3.5.6 Operator ihd/dt and the Time-Dependent Schrodinger Equation, 69 3.5.7 Relation Between Time-Independent and Time-Dependent Schrodinger Equations, 70 3.5.8 Average Values of an Observable (also Called Expectation Value), 71 3.5.9 Heisenberg Uncertainty Principle, 71 3.6 Summary of Postulates of Quantum Mechanics, 74 3.7 Conclusion, 75 References, 75 4 Hydrogen Atom, 76 4.1 Introduction, 76 4.2 Hydrogen Atom in the Ground State, 76 4.2.1 Wavefunction, 77 4.2.2 Energy, 78 4.2.3 Radial Probability Distribution of Electron, 79 CONTENTS ix 4.2.4 Most Probable Distance and Average Distance, 80 4.2.5 Average Potential Energy and Virial Theorem, 81 4.3 H Atom in Excited States, 82 4.3.1 Energies, 82 4.3.2 Wavefunctions, 83 4.3.3 Radial Probability Distribution Function and Average Distance, 87 4.3.4 Emission Spectra, 88 4.3.5 Degeneracy of H-atom Orbitals Can Be Removed by a Magnetic Field, 90 4.4 Conclusion, 92 5 Atoms and the Variational Principle, 93 5.1 Introduction, 93 5.2 Vanational Principle, 93 5.2.1 Introducing the Variational Principle, 93 5.2.2 Justification of the Variational Principle, 94 5.3 He Atom, 98 5.3.1 Ground State of He, 98 5.3.2 Indistinguishability of Electrons, 103 5.3.3 Excited States of He Described by the Product of One-Electron Trial Functions (Orbitals), 103 5.4 Electron Spin and Pauli Exclusion Principle, 104 5.4.1 Energy Splitting in a Magnetic Field, Electron Paramagnetic Resonance, 104 5.4.2 Spin Variables, 107 5.4.3 Antisymmetry Postulate (Pauli Exclusion Principle), 109 5.4.4 Singlet-Triplet Splitting: Magnetic Forces Negligible, 111 5.5 Many-Electron Atoms, 112 5.5.1 Atomic Number Z and lonization Energy, 112 5.5.2 Electronic Structure of the First Three Elements, 113 5.5.3 Aufbau Principle and the Periodic Table, 115 5.5.4 Periodic Properties of the Elements, 120 5.6 Spin-Orbit Interactions of Electrons in Atoms, 122 5.6.1 Angular Momentum and Vector Model of Atoms, 123 5.6.2 Atomic Term Symbols, 125 5.7 Conclusion, 127 References, 127 6 A Quantitative View of Chemical Bonding, 128 6.1 Introduction, 128 6.2 H^ Molecular Ion, 129 6.2.1 Electron Described by Exact Wavefunction, 129 6.2.2 Electron Density and the Chemical Bond, 131 6.2.3 Electron Described by the Linear Combination of Atomic Orbitals (LCAO) Wavefunction, 133 x CONTENTS 6.2.4 Comparison of Box Model and LCAO Method, 136 6.2.5 Excited State of H\: Bonding and Antibonding Orbitals, 138 6.3 H2: A Two-Electron System, 139 6.3.1 Rigorous Treatment, 139 6.3.2 Product of One-Electron Wavefunctions, 141 6.3.3 Indistinguishability of Electrons, 143 6.3.4 Pauli Exclusion Principle: Electronic Wavefunctions Must Be Antisymmetric, 146 6.4 Tunneling, 148 6.4.1 Electron Oscillating Between Protons a and b, 148 6.4.2 Tunneling Barrier and Frequency of Oscillation, 148 6.4.3 Importance of Tunneling in Redox Chemistry, 148 6.5 Conclusions, 149 References, 149 7 Bonding Described by Electron Pairs and Molecular Orbitals, 150 7.1 Introduction, 150 7.2 Electron Pair Bonds, 150 7.2.1 Connectivity of Atoms in Three-Atom Molecules, 151 7.2.2 Geometries for Electron Pair Bonds, 154 7.2.3 Limitations of the Electron Pair Model, 160 7.3 Molecular Orbitals, 161 7.3.1 Homonuclear Diatomics, 161 7.3.2 Heteronuclear Diatomics, 167 7.3.3 Triatomics (H2O), 170 7.3.4 Polyatomics, 174 7.4 Polarity, Bond length, and Elasticity, 177 7.4.1 Polarity of Bonds and Electronegativity, 177 7.4.2 Covalent Radii and Van der Waals Radii, 179 7.4.3 Stretching, Bending, and Torsion of Bonds, 182 7.5 Conclusions, 188 References, 188 8 Molecules with n-Electron Systems, 189 8.1 Introduction, 189 8.2 Bonding Properties of 7t-Electrons, 190 8.2.1 a -Bonded Molecular Skeleton and tt -Electrons, 190 8.2.2 Overview of Models for it-Systems, 192 8.3 Free Electron Molecular Orbital (FEMO) Model, 194 8.3.1 Ethene, Butadiene, Amidinium 7i-Electron Chains, 194 8.3.2 Benzene: A Tt-Electron Ring, 195 8.3.3 Charge Density dQ/ds, 197 8.3.4 Branched Molecules, 200 8.4 Bondlength Consistent With Total it-Electron Density Method (BCD), 203 8.5 Principles of Density Functional Theory (DFT), 209 8.6 HMO Model, 210 8.6.1 Wavefunctions and Energies, 210 CONTENTS xi 8.6.2 Application of the HMO Method to 7t-Electron Chains, 213 8.6.3 Bond Length and HMO Bond Order, 215 8.7 Resonance, 216 8.8 Conclusions, 218 References, 219 9 Absorption of Light, 220 9.1 Introduction, 220 9.2 Excitation of it-Electron Systems, 220 9.2.1 Basic Experimental Facts, 220 9.2.2 Absorption Maxima of Dyes, 226 9.2.3 Strength and Polarization of Absorption Bands, 231 9.2.4 Hetero-Atoms as Probes for Electron Distribution, 235 9.2.5 HOMO-LUMO Gap by Bond Alternation, 239 9.2.6 Cyclic jr-Systems, 242 9.2.7 Coupling of n-Electrons, 247 9.3 Optical Activity, 249 9.3.1 Rotatory Dispersion, 250 9.3.2 Ellipticity and Circular Dichroism, 251 9.3.3 Anisotropy Factor g for Model in Fig. 9.23, 254 9.3.4 Absolute Configuration of Chiral Molecules, 255 9.3.5 Circular Dichroism of Spirobisanthracene, 255 9.3.6 Circular Dichroism of Chiral Cyanine Dye, 258 9.4 Conclusions, 260 References, 260 10 Emission of Light, 261 10.1 Introduction, 261 10.2 Spontaneous Emission, 261 10.2.1 Fluorescence, 262 10.2.2 Phosphorescence and Triplet States, 267 10.2.3 Relative Energetics of Fluorescence, Phosphorescence, and Absorption, 270 10.2.4 Quenching of Fluorescence, 272 10.2.5 Absorption from Excited States, 273 10.3 Stimulated Emission and Laser Action, 275 10.3.1 Inversion of Population, 276 10.3.2 Dye Laser Operation, 276 10.3.3 Excimer and Exciplex Laser, 279 10.4 Conclusions, 279 References, 279 11 Nuclei: Particle and Wave Properties, 280 11.1 Introduction, 280 11.2 Rotational Motion of Molecules, 281 11.2.1 Diatomic Quantum-Mechanical Rotator, 281 11.2.2 Polyatomic Molecules, 284 11.2.3 Rotational Spectra, 287 xii CONTENTS 11.3 Vibrational Motion of Molecules, 293 11.3.1 Classical Oscillator, 293 11.3.2 Quantum-Mechanical Harmonic Oscillator, 296 11.3.3 Vibrational-Rotational Spectra, 301 11.3.4 Quantum-Mechanical Anharmonic Oscillator, 310 11.4 Raman Spectra, 315 11.4.1 Rayleigh Scattering, 315 11.4.2 Raman Spectroscopy, 317 11.4.3 Rotational Raman Spectra of Heteronuclear Diatomic Molecules, 318 11.4.4 Raman Spectra of Poly atomics, 322 11.5 Vibrational Structure of Electronic Spectra, 324 11.5.1 Franck-Condon Principle, 325 11.5.2 Photoelectron Spectroscopy, 328 11.5.3 Polyatomic Molecules, 331 11.6 Conclusion, 336 References, 336 12 Nuclear Spin, 337 12.1 Introduction, 337 12.2 Nuclear Spin: Fundamentals, 337 12.2.1 Spin of Protons in H2, 337 12.2.2 Antisymmetry of Total Wavefunction of a Molecule Including Electrons and Nuclei, 338 12.2.3 Nuclei With Half-Integer Spin (Antisymmetric Total Wavefunction) and Nuclei With Integral Spin (Symmetric Total Wavefunction), 340 12.3 Nuclear Magnetic Resonance (NMR), 343 12.3.1 Fundamentals, 343 12.3.2 Chemical Shift, 345 12.3.3 Fine Structure of NMR Spectra, 347 12.3.4 NMR Spectroscopy for Determination of Protein Structures in Solution, 349 12.3.5 Magnetic Resonance Imaging (MRI), 350 12.4 Conclusion, 350 References, 350 13 Solids and Intermolecular Forces, 351 13.1 Introduction, 351 13.2 Ionic Crystals, 352 13.2.1 Bond Energy of an Ion Pair, 352 13.2.2 Lattice Types, 354 13.3 Metals, 358 13.3.1 Free Electron Model for Conduction Electrons, 358 13.3.2 Cohesion Energy of Metals, 364 133.3 Quantum Wires and Nanostructure, 366 CONTENTS xlii 13.4 Semiconductors, 369 13.4.1 Soliton Conductors: Polyacetylene, 369 13.4.2 Silicon, 370 13.4.3 Semiconductor Bandgap, 371 13.4.4 Semiconductor Quantum Dots, 372 13.5 Molecular Crystals and Intermolecular Forces, 374 13.5.1 Electrostatic Forces, the Dipole, 375 13.5.2 Hydrogen Bonds, 378 13.5.3 Induction Forces, 381 13.5.4 Dispersion Forces, 383 13.6 Conclusions, 386 References, 386 14 Thermal Motion of Molecules, 387 14.1 Introduction, 387 14.2 Kinetic Gas Theory and Temperature, 387 14.2.1 Thermal Motion and Pressure, 388 14.2.2 Avogadro's Law, 395 14.2.3 Thermal Equilibration and Heat, 397 14.2.4 Ideal Gas Law and the Definition of Absolute Temperature, 397 14.2.5 Law of Partial Pressures, 401 14.3 Speed and Collisions of Gas Molecules, 402 14.3.1 Average Speed of Molecules in a Gas, 402 14.3.2 Mean Free Path and Number of Collisions, 405 14.3.3 Diffusion, 408 14.3.4 Viscosity Arising from Collisions of Molecules, 422 14.4 Thermal Motion in Liquids, 426 14.4.1 Collisions in Liquids, 426 14.4.2 Diffusion Coefficient D of a Liquid, 427 14.4.3 Viscosity of a Liquid, 428 14.4.4 Stokes-Einstein Equation, 429 14.5 Conclusions, 431 References, 431 15 Energy Distribution in Molecular Assemblies, 433 15.1 Introduction, 433 15.2 The Boltzmann Distribution Law, 434 15.2.1 System Consisting of Two Quantum States, 434 15.2.2 Systems Consisting of Many Quantum States, 436 15.2.3 Internal Energy U, 438 15.3 Electronic Energy, 439 15.4 Vibrational Energy, 440 15.4.1 Population Number Nn of a Harmonic Oscillator, 441 15.4.2 Internal Energy Uvn, of Diatomic Molecules, 444 15.4.3 Internal Energy Uvn, of Polyatomic Molecules, 446 xiv CONTENTS 15.5 Rotational Energy, 448 15.5.1 Population Number Nj of Rigid Rotator (Heteronuclear Molecules), 449 15.5.2 Internal Energy UI0t of Rotation (Heteronuclear Molecules), 451 15.5.3 Homonuclear Diatomic Molecules: Ortho- and Para-H2, 453 15.6 Translational Energy, 455 15.6.1 Internal Energy [/trans of Translation According to Quantum Mechanics, 455 15.6.2 Maxwell-Boltzmann Distribution of Speeds, 456 15.7 Characteristic Temperature, 462 15.8 Proving the Boltzmann Distribution for Distinguishable Particles, 463 15.8.1 Distribution of N Particles Among Three Levels with Given Internal Energy, 463 15.8.2 Rigorous Treatment, 468 15.9 Proving the Boltzmann Distribution for Indistinguishable Particles (High Temperature), 469 15.9.1 Number of Available Quantum States, 469 15.9.2 Number of Representations and Boltzmann Law, 470 15.9.3 Calculating the Internal Energy U of an Ideal Atomic Gas, 471 15.9.4 Relation Between 0 and T, 472 15.10 Energy Distribution of Fermions and Bosons Among Quantum States, 472 15.11 Conclusions, 475 Reference, 475 16 Work w, Heat q, and Internal Energy U, 476 16.1 Introduction, 476 16.2 Thermodynamic Systems, 477 16.2.1 Defining System and Surroundings, 477 16.2.2 Defining Thermodynamic States, 477 16.2.3 Change of State, 480 16.3 Change of State at Constant Volume (Isochoric Process), 481 16.3.1 Change of Internal Energy A U and the Heat q, 482 16.3.2 Heat Capacity Cy: Definition, 484 16.3.3 Translational Contribution to Cy of a Gas, 485 16.3.4 Rotational and Vibrational Contributions to Cy of a Gas, 486 16.3.5 Ortho- and Para-Hj: Fascinating Quantum Effects on Cv, 488 16.3.6 Electronic Contribution to Cy (Cy,ei), 489 16.3.7 Heat Capacity and Characteristic Temperature, 490 16.3.8 Cv of Solids, 491 CONTENTS XV 16.4 Change of State at Constant Pressure (Isobaric Process), 494 16.4.1 Change of Internal Energy AU: Heat q and work w, 494 16.4.2 Enthalpy H and Heat Capacity Cp: Definition, 495 16.5 Heat Exchange and Chemical Reactions, 498 16.5.1 Reaction at Constant Volume: AU, 498 16.5.2 Reaction at Constant Pressure: AH, 501 16.5.3 Temperature Dependence of AU and AH, 502 16.5.4 Molar Enthalpies of Formation from Elements AfH°, 505 16.5.5 Molar Enthalpy of Reaction Ar#°, 505 16.5.6 Bond Enthalpies and Bond Energies, 508 16.5.7 Enthalpies and Reaction Cycles, 509 16.6 Conclusions, 510 References, 511 17 Reversible Work w^y, Reversible Heat ^rev, and Entropy S, 512 17.1 Introduction, 512 17.2 Irreversible and Reversible Changes of State, 513 17.2.1 Irreversible Changes, 513 17.2.2 Reversible Changes, 513 17.3 Counting the Number of Representations of a Thermodynamic State, Q, 523 17.3.1 Distribution Possibilities, 523 17.3.2 Number of Representations £2 of an Atomic Gas in a Given Thermodynamic State, 526 17.4 The Entropy: S = k In ft, 529 17.4.1 Entropy of Subsystems, 529 17.4.2 Entropy of Atomic Gas: Sackur-Tetrode Equation, 530 17.5 Entropy Change AS, 533 17.5.1 Temperature Equilibration: Entropy Increase, 534 17.5.2 Mixing: Entropy Increase, 536 17.5.3 Entropy Cannot Decrease for an Isolated System, 537 17.5.4 Entropy Can Decrease in Closed Systems, 537 17.6 Heat and Entropy Change, 537 17.6.1 Heat and Entropy Change for an Ideal Gas, 538 17.6.2 Cyclic Processes (AS — 0) and Processes in Isolated Systems (AS 0), 542 17.6.3 Heat and Entropy Change in Arbitrary Processes, 542 17.7 Thermodynamic Temperature Scale and Cooling, 543 17.7.1 Thermodynamic Temperature Scale, 543 17.7.2 How Low Can Temperature Go?, 547 17.8 Entropies of Substances, 547 17.8.1 Entropy of an Atomic Gas, 550 17.8.2 Entropy of Diatomic Gases, 553 17.8.3 Entropy of Polyatomic Gases, 555 17.8.4 Entropy of Different Substances, 557 xvi CONTENTS 17.9 Laws of Thermodynamics, 559 17.10 Conclusions, 561 References, 561 18 General Conditions for Spontaneity and its Application to Equilibria of Ideal Gases and Dilute Solutions, 562 18.1 Introduction, 562 18.2 General Conditions for Spontaneity, 563 18.2.1 Helmholtz Energy A, 565 18.2.2 Gibbs Energy G, 566 18.3 AG and its Dependence on Temperature, 567 18.3.1 Molar Gibbs Energy of Formation from Elements AfG°, 567 18.3.2 Molar Gibbs Energy of Reaction ArG°, 567 18.3.3 Temperature Dependence of AG°, 568 18.4 Pressure Dependence of AG in Ideal Gases, 570 18.4.1 Vapor Pressure (Clausius-Clapeyron Equation), 572 18.4.2 Chemical Evolution of a Gas, 574 18.5 AG and Chemical Equilibrium in Ideal Gases, 575 18.5.1 Formal Derivation of Mass Action Law, 575 18.5.2 Mass Action Law: A Direct Consequence of the Relation Between Work and Heat, 578 18.5.3 Applying the Mass Action Law, 581 18.5.4 Temperature Dependence of Equilibrium Constant K, 584 18.5.5 Pressure Changes and Equilibrium, 588 18.5.6 Reactions Involving Gases and Immiscible Condensed Species, 589 18.5.7 Equilibrium Constant from Molecular Properties, 590 18.6 AG and Equilibrium in Dilute Solution, 593 18.6.1 Osmotic Pressure and Concentration, 593 18.6.2 Depression of Vapor Pressure (Raoult's law), 596 18.6.3 Elevation of Boiling Point and Depression of Melting Point, 600 18.6.4 Mass Action Law (Solutions of Neutral Particles), 602 18.6.5 Mass Action Law (Solutions of Charged Particles), 604 18.6.6 Gibbs Energy of Formation in Aqueous Solution, 604 18.6.7 Part of Reactants or Products in Condensed or Gaseous State, 607 18.7 Conclusions, 608 References, 608 19 Formal Thermodynamics and its Application to Phase Equilibria, 609 19.1 Introduction, 609 19.2 Internal Energy, Enthalpy, Work, and Heat, 609 19.2.1 Work, 610 19.2.2 Heat, 611 CONTENTS xvii 19.2.3 Relating U and H to Measurable Quantities, 612 19.2.4 Maxwell Relations, 615 19.2.5 An Important Application: Calculating Cp — Cy, 615 19.3 Spontaneity and Free Energy, 617 19.3.1 Helmholtz Energy A, 618 19.3.2 Gibbs Energy G, 619 19.4 Phase Equilibria and Phase Transitions, 620 19.4.1 Solid-Liquid Equilibria, 622 19.4.2 Liquid-Gas and Solid-Gas Equilibria, 624 19.4.3 Phase Diagrams and Phase Rule, 626 19.5 Conclusions, 630 References, 630 20 Real Gases, 631 20.1 Introduction, 631 20.2 AG for Real Gases and the Fugacity, 631 20.3 Equations of State for Real Gases, 634 20.3.1 Hard Sphere Gas, 634 20.3.2 Van der Waals Equation, 637 20.3.3 Critical Point and Van der Waals Constants, 638 20.3.4 Virial Equation of State, 641 20.4 Change of State of Real Gases, 644 20.4.1 Adiabatic Expansion into Vacuum, 644 20.4.2 Joule-Thomson Effect, 646 20.5 Chemical Equilibria Involving Real Gases, 649 20.6 Conclusions, 651 References, 651 21 Real Solutions, 652 21.1 Introduction, 652 21.2 Partial Molar Quantities and Thermodynamics of Multicomponent Systems, 652 21.2.1 Partial Molar Volume, 653 21.2.2 Chemical Potential, 654 21.2.3 Thermodynamic Relations, 655 21.3 Activities and Activity Coefficient for Real Solutions, 657 21.3.1 Activity from Vapor Pressure Above a Solution, 657 21.3.2 Activity from Osmotic Pressure, 659 21.4 Phase Transitions of Solutions, 661 21.4.1 Elevation of Boiling Point and Depression of Melting Point, 661 21.4.2 Solutions with Two Volatile Components, 663 21.5 Mass Action Law For Reactions in Solution, 665 21.6 Electrolyte Solutions and the Debye-Hiickel Theory, 667 21.6.1 Debye-Hiickel Theory for Electrolytes, 667 21.7 Conclusions, 671 References, 671 xviii CONTENTS 22 Reaction Equilibria in Aqueous Solutions and Biosystems, 672 22.1 Introduction, 672 22.2 Proton Transfer Reactions: Dissociation of Weak Acids, 673 22.2.1 Henderson-Hasselbalch Equation, 673 22.2.2 Degree of Dissociation in Aqueous Solution, 675 22.2.3 Degree of Dissociation in a Buffer Solution, 676 22.2.4 Titration Curve of a Weak Acid, 677 22.3 Stepwise Proton Transfer, 678 22.3.1 Diprotic Acid, 678 22.3.2 Amino Acids, 681 22.4 Electron Transfer Reactions, 682 22.4.1 Electron Transfer from Metal to Proton: Dissolution of Metals in Acid, 682 22.4.2 Electron Transfer from Metal 1 to Metal 2 Ion: Coupled Redox Reactions, 684 22.4.3 Electron Transfer to Proton at pH 7: AG°', 685 22.4.4 Photoinduced Electron Transfer, 686 22.5 Electron Transfer Coupled with Proton Transfer, 688 22.6 Group Transfer Reactions in Biochemistry, 691 22.6.1 Group Transfer Potential, 692 22.6.2 Coupled Reactions in Biology, 692 22.7 Bioenergetics, 693 22.7.1 Synthesis of Glucose, 694 22.7.2 Combustion of Glucose, 695 22.7.3 Energy Balance of Formation and Degradation (Combustion) of Glucose, 695 22.8 Conclusions, 696 References, 696 23 Chemical Reactions in Electrochemical Cells, 697 23.1 Introduction, 697 23.2 AG and Potential E of an Electrochemical Cell, 697 23.3 Simple Cells and Nernst Equation, 701 23.3.1 Metal/Metal Ions, 701 23.3.2 Gas Electrodes, 704 23.3.3 Nernst Equation and Standard Potential, 705 23.4 Standard Potential £° and Reference Electrodes, 707 23.4.1 Practical Determination of £°, 708 23.4.2 Absolute Electrode Potential, 709 23.5 Use of Electrochemical Cells for Thermodynamic Measurements, 714 23.5.1 pH Electrodes, 714 23.5.2 Measurement of Mean Activity Coefficient y±, 716 23.53 Measurement of Equilibrium Constant, 718 23.5.4 Liquid-Liquid Junctions, 719 23.6 Applications of Electrochemical Cells, 721 23.6.1 Galvanic Cells: Batteries and Accumulators, 721 CONTENTS Xix 23.6.2 Fuel Cells, 724 23.6.3 Electrolysis and Electrosynthesis, 725 23.6.4 Overvoltage, 727 23.7 Conductivity of Electrolyte Solutions, 728 23.7.1 Mobility of Ions, 728 23.7.2 Generalization, 730 23.7.3 Mobility of H+, 731 23.7.4 Ion Transport through Membranes, 732 23.8 Conclusions, 733 References, 733 24 Chemical Kinetics, 735 24.1 Introduction, 735 24.2 Collision Theory for Gas Reactions, 736 24.2.1 Counting the Number of Collisions, 736 24.2.2 Activation, 737 24.2.3 Steric Factor, 740 24.3 Rate Equation for Elementary Bimolecular Reactions, 740 24.3.1 Rate Constant and Frequency Factor for a Gas-Phase Reaction, 740 24.3.2 Rate Constant and Frequency Factor for a Reaction in Solution, 745 24.4 Rate Laws, 748 24.4.1 What is a Rate Law?, 749 24.4.2 Zero-Order Rate Law, 749 24.4.3 First-Order Rate Law, 750 24.4.4 Second-Order Rate Law, 752 24.5 Activation Energy and Frequency Factor, 755 24.5.1 Arrhenius Plot, 755 24.5.2 The Chemist's Rule of Thumb, 756 24.6 Combinations of Elementary Reactions, 756 24.6.1 Reactions Leading to Equilibrium, 756 24.6.2 Parallel Reactions, 759 24.6.3 Consecutive Reactions, 760 24.7 Complex Reactions, 761 24.7.1 Approximation Methods, 761 24.7.2 Lindemann-Hinshelwood Mechanism, 764 24.7.3 Chain Reactions, 767 24.7.4 Enzyme Reactions (Michaelis-Menten Mechanism), 769 24.7.5 Autocatalytic Reactions, 772 24.7.6 Bistability, 778 24.7.7 Oscillating Reactions, 780 24.7.8 Chemical Waves, 784 24.8 Experimental Methods, 786 24.8.1 Monitor Reaction Progress and Sampling, 786 24.8.2 How Methods, 787 24.8.3 Quenching Methods, 788 xx CONTENTS 24.8.4 Flash Photolysis, 789 24.8.5 Relaxation Method, 791 24.9 Conclusions, 794 References, 794 25 Transition States and Chemical Reactions, 795 25.1 Introduction, 795 25.2 Transition State in a Statistical View, 795 25.2.1 Transition State Theory for Bimolecular Reactions, 796 25.2.2 Transition State Theory for Unimolecular Reactions, 806 25.2.3 Applications of Transition State Theory, 808 25.3 Transition State in a Dynamical View, 813 25.3.1 State to State Reaction Rates, 813 25.3.2 Transition State Spectroscopy, 816 25.3.3 Rate Constant kt(E) from Reaction Cross-Sections, 817 25.3.4 Relation Between kT(E) and the Rate Constant kt(T), 819 25.4 Transition State Theory and Reactions in Solution, 820 25.4.1 Unimolecular Reactions and Frictional Coupling, 821 25.4.2 Dissociation Reactions, 823 25.4.3 Proton Transfer Reactions, 826 25.5 Conclusions, 827 References, 828 26 Macromolecules, 829 26.1 Introduction, 829 26.2 Random Coil, 829 26.2.1 A Chain of Statistical Chain Elements, 831 26.3 Measuring the Length of Statistical Chain Elements, 835 26.3.1 Light Scattering, 835 26.3.2 Hydrodynamics: Coil Approximated as a Sphere, 839 26.3.3 Hydrodynamics: Macroscopic Modeling, 842 26.4 Uncoiling a Coil and its Recoiling, 848 26.4.1 Unraveling Coil by Force Applied at Chain Ends, 848 26.4.2 Fully Unraveling a Coil in a Flowing Medium, 852 26.4.3 Partially Unraveling a Coil in a Flowing Medium, 854 26.4.4 Restoring Coil, 857 26.5 Proteins as Biopolymers, 859 26.6 Motion Through Entangled Polymer Chains, 861 26.6.1 Moving Random Coil by Winding Through Meshwork: Gel Electrophoresis of DNA Fragments, 863 26.7 Rubber Elasticity, 865 26.8 Conclusion, 867 References, 867 27 Organized Molecular Assemblies, 869 27.1 Introduction, 869 27.2 Liquid Surfaces and Liquid/Liquid Interfaces, 869 27.2.1 Surface Tension and Interfacial Tension, 869 CONTENTS XXJ 27.2.2 Surface Active Molecules (Surfactants), 874 27.3 Films on Solid Surfaces, 880 27.3.1 Langmuir-Blodgett Films (LB Films), 880 27.3.2 Self-Assembled Monolayers (SAM), 881 27.3.3 Contact Angle, 882 27.4 Micelles, 883 27.4.1 Spherical Micelles: Critical Micelle Concentration, 885 27.4.2 Geometry of Packing, 891 27.5 Membranes, 892 27.5.1 Liposomes, 892 27.5.2 Soap lamella, 893 27.5.3 Black lipid membranes, 894 27.6 Biomembranes, 896 27.6.1 Lateral Diffusion, 896 27.6.2 Ion Transport Through a Membrane, 896 27.6.3 Transport of Small Protein Through a Membrane, 899 27.7 Liquid Crystals, 900 27.7.1 Optics Applications of Liquid Crystals, 902 27.8 Conclusions, 906 References, 906 28 Supramolecular Machines, 908 28.1 Introduction, 908 28.2 Idea of a Supramolecular Machine, 909 28.2.1 A Simple Energy Transduction Device, 909 28.2.2 Programmed Interlocking Molecules, 910 28.3 Manipulating Photon Motion, 913 28.3.1 Energy Transfer Between Dye Molecules: FRET, Ruler in Nanometer Range; SNOM, 913 28.3.2 Functional Unit by Coupling Chromophores, 920 28.3.3 Dye Aggregate as Energy-Harvesting Device, 921 28.3.4 Solar Energy Harvesting in Biosystems, 926 28.3.5 Manipulating Luminescence Lifetime by Programming Echo Radiation Field, 927 28.4 Manipulating Electron Motion, 930 28.4.1 Photoinduced Electron Transfer in Designed Monolayer Assemblies, 930 28.4.2 Tunneling Current Through Monolayers, 932 28.4.3 Conduction Through Single Molecules, 935 28.4.4 Conjugated Molecular Tethers, 940 28.4.5 Electron Transfer in Proteins, 941 28.4.6 Solar Energy Conversion: The Electron Pump of Plants and Bacteria, 943 28.4.7 Electron Transfer in Soft Medium, 947 28.4.8 Inverted Region of Electron Transfer Reactions, 949 28.4.9 Artificial Photoinduced Electron Pumping, 951 28.5 Manipulating Nuclear Motion, 952 28.5.1 Light-Induced Change of Monolayer Properties, 952 xxii CONTENTS 28.5.2 Mechanical Switching Devices, 954 28.5.3 Photoinduced Sequence of Amplification Steps: The Visual System, 955 28.5.4 Solar Energy Conversion in Halobacteria, 956 28.5.5 Biomotors, 961 28.6 Conclusions, 969 References, 969 29 Origin of Life: Matter Carrying Information, 973 29.1 Introduction, 973 29.2 Investigation of Complex Systems, 974 29.2.1 Need for Simplifying Models, 974 29.2.2 Increasing Simplification with Increasing Stages of Complexity, 974 29.3 Can Life Emerge by Physicochemical Processes?, 974 29.3.1 Bioevolution as a Process of Learning How to Survive as a Species, 974 29.3.2 Model Case for the Learning Mechanism, 975 29.4 Modeling the Emergence of the Genetic Apparatus, 977 29.4.1 Basic Questions, 977 29.4.2 Evolution of the Universe and Evolution of Life: The Big Bang and the Tiny Bang, 980 29.4.3 Paradigm of Present Attempt to Understand the Origin of Life, 980 29.4.4 General Conditions for Life to Come into Being: Periodicity in Time, Compartmentalization, and Structural Diversity, 981 29.4.5 Definition of Life in the Present Context, 982 29.4.6 Modelling a Continuous Sequence of Physicochemical Processes Leading to a Genetic Apparatus, 982 29.5 General Aspects of Life's Emergence and Evolution, 986 29.5.1 Information and Knowledge, 986 29.5.2 Processing Information, Genesis of Information and Knowledge, and the Maxwell Demon, 986 29.5.3 Limits of Physicochemical Ways of Thinking, 990 29.6 Conclusions, 993 References, 993 Index, 995 List of Foundations 1 Chapter 1 2 Chapter 2 3 Chapter 3 3.1 Electron in a Potential Well of Finite Depth 3.1.1 Symmetric Solutions 3.1.2 Antisymmetric Solutions 3.1.3 Numerical Evaluation 3.2 Orthogonality 3.3 Uncertainty Principle 3.3.1 Uncertainty in the Momentum 3.3.2 Uncertainty in the Position 3.3.3 Uncertainty Product 3.3.4 Example: Gaussian Distribution of Momenta 4 Chapter 4 4.1 H Atom: Solution of the Schrodinger Equation 4.2 H Atom: Angular and Radial Wavefunctions 4.2.1 The Angular Solution 4.2.2 The Radial Solution 4.2.3 The Total Wavefunction 5 Chapter 5 5.1 Proof of Variational Principle 5.2 First Order Perturbation Theory 5.2.1 Example: Electron in a Potential Well 5.3 Perturbation Theory (Rigorous Treatment) 5.3.1 Example: Electron in a Potential Well 5.4 He-Atom: Repulsion Energy 5.5 The Self-Consistent Field approximation 5.6 Atomic Term Symbols 6 Chapter 6 6.1 H^ Ion: Exact Wavefunction and Energy 6.1.1 Energy 6.1.2 Wavefunction for the Equilibrium Distance 6.1.3 Virial Theorem for Molecules 6.2 Evaluation of LCAO Integrals in H^ 6.3 Oscillation of Electron between Protons at Distance d (Tunneling) 6.3.1 Calculating E\ and £2 in H^ for Large Distance d 6.3.2 Calculating £2 — £1 6.3.3 Calculating the Time-Dependent Probability Density p 6.3.4 Period of Oscillation 6.3.5 Tunneling Probability xxiii xxiv LIST OF FOUNDATIONS 7 Chapter 7 7.1 LCAO-Treatment of Heteronuclear Diatomic Molecules 8 Chapter 8 8.1 Construction of V(s) in Figure 8.3 8.2 Free-Electron Model 8.2.1 Case 1: Symmetric Wavefunctions 8.2.2 Case 2: Antisymmetric Wavefunctions 8.2.3 Energies 8.2.4 Normalization 8.3 Free-Electron Model, Representation by Determinants 8.4 HMO Model 8.4.1 Finding the Minimum of e 8.4.2 Solving a system of N linear equations with constant coefficients 8.4.3 Example: butadiene 8.4.4 Example: benzene 8.5 Fullerene 9 Chapter 9 9.1 Integrated Absorption: Classical Oscillator 9.1.1 Absorbed Power in a Radiation Beam and Absorption Coefficient e 9.1.2 Calculating the Absorption Coefficient e Classically 9.1.3 Resonance Curve for e: Calculating Jband £ • du 9.1.4 Integrated Absorption Power 9.1.5 Derivation of Equation (9.4) for the Intensity / 9.2 Oscillator Strength: Quantum Mechanical Treatment 9.2.1 Quantum Mechanical Expression for / 9.3 Classical and Quantum Mechanical Description of Light Absorption 9.3.1 Light Absorption Calculated from the Schrodinger Equation 9.3.2 Power Absorbed by the Molecule 9.3.3 Classical Oscillator 9.3.4 Equivalence of Classical and Quantum Mechanical Treatment 9.4 Coupling Transitions with Parallel Transition Moments 9.4.1 Replacing Quantum Mechanical System by Coupled Classical Oscillators 9.4.2 Doubly Occupied Orbitals 9.5 Normal Modes of Coupled Oscillators 9.5.1 Resonance Frequencies of Two Coupled Oscillators 9.5.2 Oscillator Strength of Two Coupled Oscillators 9.5.3 Coupling Two Identical Oscillators 10 Chapter 10 10.1 Fluorescence Life Time 10.1.1 Antenna Equation of Hertz 10.1.2 Natural Lifetime 10.1.3 Lifetime and Line Width LIST OF FOUNDATIONS xxv 10.2 Calculation of Repulsion Integrals 10.2.1 Deriving Equations for the Integrals 10.2.2 Numerical Integration 11 Chapter 11 11.1 Rotator: Solution of the Schrodinger Equation 11.1.1 Diatomics 11.1.2 Polyatomics 11.2 Quantum-Mechanical Treatment of the Harmonic Oscillator 11.2.1 Diatomics 11.2.2 Symmetric wavefunctions 11.2.3 Antisymmetric wavefunctions 11.3 Selection Rules for Rotation of Linear Molecules (Absorption Spectra) 11.3.1 Transition Moment 11.3.2 Intensity Distribution of Absorption Lines 11.4 Centrifugal Effect on Energy of Diatomic Rotator 11.5 Selection Rules for Vibration (Absorption Spectra) 11.5.1 Diatomic Molecules 11.5.2 Polyatomic Molecules 11.6 Selection Rules for Rotation of Linear Molecules (Raman Spectra) 11.6.1 Transition Moment 11.6.2 Intensity of Raman Lines 11.7 Selection Rules for Vibration of Diatomic Molecules (Raman Spectra) 12 Chapter 12 13 Chapter 13 13.1 Some Features of Crystal Structures and Lattices 13.2 Polarizability of a Conducting Sphere 14 Chapter 14 14.1 The Random Walk in Three Dimensions 14.2 Intermolecular Forces Affecting the Mean Free Path 14.3 Law of Hagen-Poiseuille 14.3.1 Flow in a Tube 14.3.2 Volume V of a Gas Flowing Through the Tube 14.3.3 Law of Hagen-Poiseuille for Liquids 15 Chapter 15 15.1 Classical Derivation of the One-Dimensional Maxwell-Boltzmann Distribution of Speeds 15.1.1 Calculation of Constant A 15.2 How to Find the Maximum of In a 15.3 Energy Distribution of Fermions and Boson 15.3.1 Fermions 15.3.2 Bosons 15.3.3 Classical Case ("boltzons") 15.3.4 Distribution Functions 15.4 Canonical and Microcanonical Ensembles 15.5 Internal Energy U as Sum of Contributions Uei, Uvn,, Urot, and U trans xxvi LIST OF FOUNDATIONS 16 Chapter 16 16.1 Deriving the Debye Function (Cy of Solids) 16.2 How to Calculate f£ ACfm ¦ AT 16.2.1 Hydrogen and Oxygen Gas Reaction, Temperature Range 298 K to 350 K 16.2.2 Hydrogen and Oxygen Gas Reaction, Temperature Range 298 K to 1500 K 16.2.3 Heating Limestone 17 Chapter 17 17.1 Number of Representations Q from Molecular Partition Function Z 17.1.1 Distinguishable Particles 17.1.2 Indistinguishable Particles 17.2 Entropy of Homonuclear Diatomic Gases 18 Chapter 18 18.1 How to Calculate AGt2 from AGTl 18.2 Relationship between the Molecular Partition Function and the Equilibrium Constant 18.3 Isotope Exchange Equilibrium 18.4 How to Determine A G° for Ions 19 Chapter 19 19.1 Some Formal Thermodynamic Relationships 19.1.1 First Order Relations (Maxwell Relations) 19.1.2 Combinations of First Order Relations 19.1.3 Second Order Relations 19.1.4 Change of Variables 19.1.5 Evaluation of Thermodynamic Functions by Measurable Quantities 19.2 Molecular Perspective on Solid-Gas Equilibria 19.2.1 Solid Argon 19.2.2 Solid-Gas Equilibrium for Argon 19.2.3 Thermodynamics of Solids 19.3 Distinguishing Between Phases 20 Chapter 20 20.1 Virial Equation of State 20.1.1 Classical Partition Function 20.2 Joule-Thomson Coefficient and Inversion Temperature 21 Chapter 21 21.1 Activity Coefficient of Solute From Activity Coefficient of Solvent 21.2 Distribution of Ions in Solution 21.2.1 Charge Distribution between Two Plates 21.2.2 Charge Distribution Around an Ion 21.2.3 Poisson Equation 22 Chapter 22 22.1 Titration of Acetic Acid by NaOH 22.1.1 Effect of Increasing Volume 22.2 Two Coupled Chemical Equilibria LIST OF FOUNDATIONS xxvii 22.2.1 Evaluation of concentrations q/2a Om- ar d 'ca2~ 22.2.2 Titration curve 23 Chapter 23 24 Chapter 24 25 Chapter 25 25.1 Thermal Rate Constants 25.2 Derivation of the Kramers formula 26 Chapter 26 26.1 Light Scattering of Macromolecules 26.1.1 Polarizability a of Macromolecules in the Field of an Incident Light Wave 26.1.2 Forward and Backward Light Scattering 26.2 Viscosity of Dilute Solutions of Polymers and Macroscopic Models 26.2.1 The Dumbbell Model 26.2.2 Viscosity of a Dilute Solution of Dumbbells 26.2.3 Dumbbells and Rotational Form Factor Crot 26.2.4 Conclusion on Viscosity of Dilute Solutions of Random Coils 26.3 Diffusion of a Random Coil in a Gel in the Absence of an Electric Field and Force-Induced Motion 26.3.1 Time r to Leave the Cage. Diffusion Coefficient Di 26.3.2 Global Diffusion of Coil. Diffusion Coefficient D 26.3.3 Force-Induced Motion of Coil 26.4 Stretching a Chain 27 Chapter 27 21.1 Head-to-Head Repulsion Energy 27.2 Clausius-Mosotti Equation 27.2.1 Permanent Dipoles in Electric Field (Simplified Model) 27.2.2 Permanent Dipoles in Electric Field (Rigorous Calculation) 27.2.3 Field Strength in a Liquid 28 Chapter 28 28.1 Energy Transfer 28.1.1 One Donor and One Acceptor in Distance r 28.1.2 Molecules in a Layer Plane 28.1.3 Relation Between r$ and do 28.1.4 Comparison of Absorbed Power in Far Field and Near Field 28.2 Energy Transfer from Exciton to Acceptor 28.2.1 Case (a): Arrangement in Figure 28.14a 28.2.2 Case (b): Arrangement in Figure 28.14b 28.3 Radiation Echo Field 28.3.1 Excited Dye Molecule Without Mirror 28.3.2 Excited Dye Molecule in the Field F of a Mirror 28.3.3 Note 1: Lifetime of Oscillator 28.3.4 Note 2: Conversion of the Hertz Equation 28.4 Electron Transfer Between Tt-Electron Systems xxviii LIST OF FOUNDATIONS 28.4.1 General Case 28.4.2 Rate of Electron Transfer 28.4.3 Evaluation of s 28.4.4 Evaluation of eeiectroniC 28.4.5 Evaluation of Rate Constant kr 28.5 Calculation of Ebarrier 28.6 Marcus Equation 28.7 Chloride Ion Pump and Sensory Receptor of Halobacteria 28.7.1 Chloride Ion Pump 28.7.2 Sensory Receptors 29 Chapter 29 29.1 Search for Logical Conditions Driving the Emergence of a Genetic Translation Device 29.2 The Emergence of a Simple Genetic Apparatus Viewed as a Supramolecular Engineering Problem. A Thought Experiment 29.2.1 A Short Template Marks the Beginning 29.2.2 Intricate Cycles of Temperature Drive Replication 29.2.3 Strand Evolution Requires Rare Replication Errors 29.2.4 Strand Lengthening-Colonization of Larger Porous Regions 29.2.5 Strand Folding: Hairpins-Most Resistant Structure 29.2.6 Aggregation of Hairpins: an Error Filter 29.2.7 Assembler Strand Guides Hairpin Aggregation 29.2.8 A New Variety (a-Monomers) Appears: a-Oligomers Formed by HA Device Enable Colonization of Larger Porous Regions 29.2.9 Breakthrough of Translational Device 29.2.10 Breakthrough of an Integrative Translation Device 29.2.11 Computer Simulation of Thought Experiment 29.3 Attempts to Model the Origin of Life 29.3.1 The Earliest Phase 29.3.2 Breaking Symmetry: Chirality of Nucleotides and Its Evolutionary Benefit 29.3.3 The Earliest HA-Device 29.3.4 The Reading Frame Requirement 29.3.5 Stage-by-Stage Evolution of the Code 29.4 Maxwell's Demon 29.5 Later Evolutionary Steps: Emergence of an Eye With Lens List of Justifications 1 Chapter 1 1.1 Diffraction on a Double Slit 2 Chapter 2 2.1 Mean Distance 7 2.2 Mean Potential Energy V 2.3 Particle in a Box Trial Function for H Atom 3 Chapter 3 3.1 Energy and Momentum of Free Electron 3.2 Energy and Momentum 4 Chapter 4 4.1 Bohr Radius 4.2 Laplace Operator for the H Atom 4.3 Probability in the 2s State of the H Atom 4.4 Calculation of Average Distance 7 for the 2pz state of the H Atom 5 Chapter 5 5.1 Ground State Energy of H Atom by Variational Principle 5.2 Ground State Energy of He+ 6 Chapter 6 6.1 Normalization Constant in Hj Wavefunction 6.2 Excited State of H+ 6.3 Hamiltonian of the H2 Molecule Compared to the Hamiltonians of Two H^ Ions 7 Chapter 7 7.1 Orthogonal Set of Hybrid Functions 7.2 Tetrahedral Hybrid Function 7.3 Stretching Force Constant of H^ Ion 7.4 Morse Function 7.4.1 Limit of Small Elongations 7.4.2 Inflection Point 7.4.3 Maximum Force 8 Chapter 8 8.1 Energies of Benzene for n — 3 8.2 Resonance of Hiickel (An + 2) Rings 8.3 HMO Model: Excited State of Ethene 9 Chapter 9 9.1 Interaction of Electron with Electric and Magnetic Field 9.2 Field Strength in a Molecule Compared to Field Strength of Light Wave 9.3 Energy Shift in Azacyanines 9.4 Shift of Energy Levels by Bond Alternation 9.5 Transition Moment Mx for Phthalocyanine xxix xxx LIST OF J USTIFICAT1ONS 9.6 Light Absorption of Porphynn 9.7 Amsotropy Factor g in Section 9.3.3 9.7.1 Proof of Relation (9.15) 10 Chapter 10 10.1 Singlet-Triplet Transition 10.2 Non-Existence of He2 11 Chapter 11 11.1 Nonrigid Rotator 11.2 Oscillator: Box Wavefunctions 11.3 Classical Oscillator: Probability Density p(x) 11.4 Rotational-Vibrational Spectra: Spacing of Absorption Lines 12 ChapterU 12.1 Raman Spectrum of N2 12.2 Spacing of Raman Lines in O2 and CO2 13 Chapter 13 13.1 Cohesion Energy in Li Metal 13.2 Dipole and Induction Energies 13.2.1 Dipole Energy (Dipoles in Line) 13.2.2 Dipole Energy (Dipoles parallel) 13.2.3 Dipole Energy (Dipoles in Angle /J) 13.2.4 Dipole in the Field of a Point Charge 13.2.5 Electric Field Strength of Dipole 13.3 Polarizability of a Conducting Plate and of a Conducting Sphere 14 Chapter 14 14.1 Collision of Heavy Particle with Light Particle 15 Chapter 15 15.1 Rotational Energy of Symmetric Top Molecules 15.2 Molecular Partition Function Ztmns of Translation 15.3 Calculation of Normalization Constant 15.4 Constant in the Maxwell-Boltzmann Distribution 15.5 Mean Speed 15.6 Occupation Probability in Lowest Quantum State 15.7 Distinguishable Particles Occupying Degenerate Energy levels 16 Chapter 16 16.1 Heat Capacity: Electronic Contribution 16.2 Limits of Debye Function of Heat Capacity 17 Chapter 17 17.1 Temperature Scale 18 Chapter 18 18.1 Equilibrium Constant of H2 + D2 ^ 2HD Equilibrium 18.2 Depression of Melting point 19 Chapter 19 19.1 Derivation of Equation for (dH/dP)T 19.2 More Precise Calculation of AHtotai m 193 Calculation of Vapor Pressure 20 Chapter 20 20.1 Definition of Ideal Gas LIST OF JUSTIFICATIONS xxxi 21 Chapter 21 21.1 Maxwell Relations 21.1.1 Derivation of Equation 21.21 21.1.2 Derivation of Equation 21.22 21.1.3 Derivation of Equation 21.23 21.2 Chemical Potential of Ideal Solution 21.3 Activity Coefficient of Solute from Activity Coefficient of Solvent 21.4 Boiling Point: Approximation for Small Temperature Difference 21.5 Depression of Freezing Point 22 Chapter 22 22.1 pH Change in Buffer Solutions 22.2 pH of Amino Acids 23 Chapter 23 23.1 Thermodynamic and Electrochemical Data 23.2 Gas Electrodes With Different Hydrogen Gas Pressures 24 Chapter 24 24.1 General Form of Second Order Reaction 24.2 Reactions Leading to Equilibrium 24.3 Different Reaction Orders in Both Reactions 24.4 Consecutive Reaction 24.5 Maximum Concentration of Intermediate 24.6 Consecutive Reaction: Special Case k'2 = £', 24.7 Autocatalytic Reaction 25 Chapter 25 25.1 Reduced Mass of Activated Complex 25.2 Isotope Effect on Reaction Rates 26 Chapter 26 26.1 Light Scattering: Backward Scattering 26.2 Light Scattering: Ratio /i35=//45° 26.3 Force Acting on Chain Ends 27 Chapter 27 21.1 Contact Angles in Figure 27.4 28 Chapter 28 28.1 Circular Dichroism and Structural Features of Chlorosomes 28.2 Electron Transfer: Tunneling Versus Thermal Activation 28.3 Proton Pump: Field of Charged Amino Acids at Chromophore
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spelling	Kuhn, Hans Verfasser aut Principles of physical chemistry by Hans Kuhn ; Horst-Dieter Försterling ; David H. Waldeck 2. ed. Hoboken, NJ Wiley 2009 XLII, 1032 S. Ill., graph. Darst. 1 CD-ROM (12 cm) txt rdacontent n rdamedia nc rdacarrier Chemistry, Physical and theoretical Physikalische Chemie (DE-588)4045959-7 gnd rswk-swf (DE-588)4123623-3 Lehrbuch gnd-content Physikalische Chemie (DE-588)4045959-7 s DE-604 Försterling, Horst-Dieter 1934- Verfasser (DE-588)141908599 aut Waldeck, David H. Verfasser aut HBZ Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016608009&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Kuhn, Hans Försterling, Horst-Dieter 1934- Waldeck, David H. Principles of physical chemistry Chemistry, Physical and theoretical Physikalische Chemie (DE-588)4045959-7 gnd
subject_GND	(DE-588)4045959-7 (DE-588)4123623-3
title	Principles of physical chemistry
title_auth	Principles of physical chemistry
title_exact_search	Principles of physical chemistry
title_exact_search_txtP	Principles of physical chemistry
title_full	Principles of physical chemistry by Hans Kuhn ; Horst-Dieter Försterling ; David H. Waldeck
title_fullStr	Principles of physical chemistry by Hans Kuhn ; Horst-Dieter Försterling ; David H. Waldeck
title_full_unstemmed	Principles of physical chemistry by Hans Kuhn ; Horst-Dieter Försterling ; David H. Waldeck
title_short	Principles of physical chemistry
title_sort	principles of physical chemistry
topic	Chemistry, Physical and theoretical Physikalische Chemie (DE-588)4045959-7 gnd
topic_facet	Chemistry, Physical and theoretical Physikalische Chemie Lehrbuch
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016608009&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
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