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• Title:Inorganic chemistry / James E. House.
  
•    
• Author/Creator:House, J. E.
  
• Published/Created:Amsterdam ; Waltham [Mass.] : Academic Press/Elsevier, 2013.
  

• Holdings

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  • Location:WOODWARD LIBRARY stacksWhere is this?
    
  • Call Number: QD151.5 .H68 2013
    
  • Number of Items:1
    
  • Status:Available
    
  • Links:Donor bookplate
    

   
• Library of Congress Subjects:Chemistry, Inorganic--Textbooks.
  
• Edition:2nd ed.
  
• Description:xiv, 832 p. : ill. (some col.) ; 25 cm
  
• Notes:Includes bibliographical references and index.
  
• ISBN:9780123851109
  0123851106
  
• Contents:Machine generated contents note: pt. 1 Structure of Atoms and Molecules
  ch. 1 Light, Electrons, and Nuclei
  1.1. Some Early Experiments in Atomic Physics
  1.2. Nature of Light
  1.3. Bohr Model
  1.4. Particle-Wave Duality
  1.5. Electronic Properties of Atoms
  1.6. Nuclear Binding Energy
  1.7. Nuclear Stability
  1.8. Types of Nuclear Decay
  1.9. Predicting Decay Modes
  ch. 2 Basic Quantum Mechanics and Atomic Structure
  2.1. Postulates
  2.2. Hydrogen Atom
  2.3. Helium Atom
  2.4. Slater Wave Functions
  2.5. Electron Configurations
  2.6. Spectroscopic States
  ch. 3 Covalent Bonding in Diatomic Molecules
  3.1. Basic Ideas of Molecular Orbital Methods
  3.2. H+2 and H2 Molecules
  3.3. Diatomic Molecules of Second-Row Elements
  3.4. Photoelectron Spectroscopy
  3.5. Heteronuclear Diatomic Molecules
  3.6. Electronegativity
  3.7. Spectroscopic States for Molecules
  ch. 4 Survey of Inorganic Structures and Bonding
  4.1. Structures of Molecules Having Single Bonds
  4.2. Resonance and Formal Charge
  4.3. Complex Structures: A Preview of Coming Attractions
  4.4. Electron-Deficient Molecules
  4.5. Structures Having Unsaturated Rings
  4.6. Bond Energies
  ch. 5 Symmetry and Molecular Orbitals
  5.1. Symmetry Elements
  5.2. Orbital Symmetry
  5.3. Brief Look at Group Theory
  5.4. Construction of Molecular Orbitals
  5.5. Orbitals and Angles
  5.6. Simple Calculations Using the Huckel Method
  pt. 2 Condensed Phases
  ch. 6 Dipole Moments and Intermolecular Interactions
  6.1. Dipole Moments
  6.2. Dipole-Dipole Forces
  6.3. Dipole-Induced Dipole Forces
  6.4. London (Dispersion) Forces
  6.5. van der Waals Equation
  6.6. Hydrogen Bonding
  6.7. Cohesion Energy and Solubility Parameters
  6.8. Solvatochromism
  ch. 7 Ionic Bonding and Structures of Solids
  7.1. Energetics of Crystal Formation
  7.2. Madelung Constants
  7.3. Kapustinskii Equation
  7.4. Ionic Sizes and Crystal Environments
  7.5. Crystal Structures
  7.6. Solubility of Ionic Compounds
  7.7. Proton and Electron Affinities
  7.8. Structures of Metals
  7.9. Defects in Crystals
  7.10. Phase Transitions in Solids
  7.11. Heat Capacity
  7.12. Hardness of Solids
  ch. 8 Dynamic Processes in Inorganic Solids
  8.1. Characteristics of Solid-State Reactions
  8.2. Kinetic Models for Reactions in Solids
  8.3. Thermal Methods of Analysis
  8.4. Effects of Pressure
  8.5. Reactions in Some Solid Inorganic Compounds
  8.6. Phase Transitions
  8.7. Reactions at Interfaces
  8.8. Diffusion in Solids
  8.9. Sintering
  8.10. Drift and Conductivity
  pt. 3 Acids, Bases, and Solvents
  ch. 9 Acid-Base Chemistry
  9.1. Arrhenius Theory
  9.2. Brønsted-Lowry Theory
  9.3. Factors Affecting the Strength of Acids and Bases
  9.4. Acid-Base Character of Oxides
  9.5. Proton Affinities
  9.6. Lewis Theory
  9.7. Catalytic Behavior of Acids and Bases
  9.8. Hard-Soft Interaction Principle (HSIP)
  9.9. Electronic Polarizabilities
  9.10. Drago Four-Parameter Equation
  ch. 10 Chemistry in Nonaqueous Solvents
  10.1. Some Common Nonaqueous Solvents
  10.2. Solvent Concept
  10.3. Amphoteric Behavior
  10.4. Coordination Model
  10.5. Chemistry in Liquid Ammonia
  10.6. Liquid Hydrogen Fluoride
  10.7. Liquid Sulfur Dioxide
  10.8. Superacids
  pt. 4 Chemistry of the Elements
  ch. 11 Chemistry of Metallic Elements
  11.1. Metallic Elements
  11.2. Band Theory
  11.3. Groups IA and IIA Metals
  11.4. Zintl Phases
  11.5. Aluminum and Beryllium
  11.6. First-Row Transition Metals
  11.7. Second- and Third-Row Transition Metals
  11.8. Alloys
  11.9. Chemistry of Transition Metals
  11.10. Lanthanides
  ch. 12 Organometallic Compounds of the Main Group Elements
  12.1. Preparation of Organometallic Compounds
  12.2. Organometallic Compounds of Group IA Metals
  12.3. Organometallic Compounds of Group IIA Metals
  12.4. Organometallic Compounds of Group IIIA Metals
  12.5. Organometallic Compounds of Group IVA Metals
  12.6. Organometallic Compounds of Group VA Elements
  12.7. Organometallic Compounds of Zn, Cd, and Hg
  ch. 13 Chemistry of Nonmetallic Elements I. Hydrogen, Boron, Oxygen, and Carbon
  13.1. Hydrogen
  13.2. Boron
  13.3. Oxygen
  13.4. Carbon
  ch. 14 Chemistry of Nonmetallic Elements II. Groups IVA and VA
  14.1. Group IVA Elements
  14.2. Nitrogen
  14.3. Phosphorus, Arsenic, Antimony, and Bismuth
  ch. 15 Chemistry of Nonmetallic Elements III. Groups VIA-VIIIA
  15.1. Sulfur, Selenium, and Tellurium
  15.2. Halogens
  15.3. Noble Gases
  pt. 5 Chemistry of Coordination Compounds
  ch. 16 Introduction to Coordination Chemistry
  16.1. Structures of Coordination Compounds
  16.2. Metal-Ligand Bonds
  16.3. Naming Coordination Compounds
  16.4. Isomerism
  16.5. Simple Valence Bond Description of Coordinate Bonds
  16.6. Magnetism
  16.7. Survey of Complexes of First-Row Metals
  16.8. Complexes of Second- and Third-Row Metals
  16.9. 18-Electron Rule
  16.10. Back Donation
  16.11. Complexes of Dinitrogen, Dioxygen, and Dihydrogen
  ch. 17 Ligand Fields and Molecular Orbitals
  17.1. Splitting of d Orbital Energies in Octahedral Fields
  17.2. Splitting of d Orbital Energies in Fields of Other Symmetry
  17.3. Factors Affecting Δ
  17.4. Consequences of Crystal Field Splitting
  17.5. Jahn-Teller Distortion
  17.6. Spectral Bands
  17.7. Molecular Orbitals in Complexes
  ch. 18 Interpretation of Spectra
  18.1. Splitting of Spectroscopic States
  18.2. Orgel Diagrams
  18.3. Racah Parameters and Quantitative Methods
  18.4. Nephelauxetic Effect
  18.5. Tanabe-Sugano Diagrams
  18.6. Lever Method
  18.7. Jorgensen's Method
  18.8. Charge Transfer Absorption
  18.9. Solvatochromism
  ch. 19 Composition and Stability of Complexes
  19.1. Composition of Complexes in Solution
  19.2. Job's Method of Continuous Variations
  19.3. Equilibria Involving Complexes
  19.4. Distribution Diagrams
  19.5. Factors Affecting the Stability of Complexes
  ch. 20 Synthesis and Reactions of Coordination Compounds
  20.1. Synthesis of Coordination Compounds
  20.2. Substitution Reactions in Octahedral Complexes
  20.3. Ligand Field Effects
  20.4. Acid-Catalyzed Reactions of Complexes
  20.5. Base-Catalyzed Reactions of Complexes
  20.6. Compensation Effect
  20.7. Linkage Isomerization
  20.8. Substitution in Square Planar Complexes
  20.9. Trans Effect
  20.10. Electron Transfer Reactions
  20.11. Reactions in Solid Coordination Compounds
  ch. 21 Complexes Containing Metal-Carbon and Metal-Metal Bonds
  21.1. Binary Metal Carbonyls
  21.2. Structures of Metal Carbonyls
  21.3. Bonding of Carbon Monoxide to Metals
  21.4. Preparation of Metal Carbonyls
  21.5. Reactions of Metal Carbonyls
  21.6. Structure and Bonding in Metal-Alkene Complexes
  21.7. Preparation of Metal-Alkene Complexes
  21.8. Chemistry of Cyclopentadienyl and Related Complexes
  21.9. Bonding in Ferrocene
  21.10. Reactions of Ferrocene and other Metallocenes
  21.11. Complexes of Benzene and Related Aromatics
  21.12. Compounds Containing Metal-Metal Bonds
  ch. 22 Coordination Compounds in Catalysis
  22.1. Elementary Steps in Catalytic Processes
  22.2. Homogeneous Catalysis
  ch. 23 Bioinorganic Chemistry
  23.1. What Metals Do in Some Living Systems
  23.2. Cytotoxicity of Some Metal Compounds
  23.3. Antimalarial Metallodrugs.