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Part 1: Basic Modern Chemistry

Chapter 1 Atoms in Modern Chemistry
1.1 The Essence of Modern Chemistry
1.2 Macroscopic methods for classifying substances
1.3 Indirect evidence for the existence of atoms: the laws of chemical bonding
1.4 Physical Structure of Atoms

Chapter 2 Chemical Formulas, Chemical Reaction Formulas, and Reaction Yields
2.1 Mole: Measurement of the mass and number of molecules
2.2 Empirical and molecular formulas
2.3 Chemical Formula and Percent Composition
2.4 Writing balanced chemical equations
2.5 Mass Relationships in Chemical Reactions
2.6 Limiting reactant and percent yield

Part 2: Chemical Bonding and Molecular Structure

Chapter 3 Chemical Bonding: Classical Techniques
3.1 Representation of molecules
3.2 Periodic Table
3.3 Forces and potential energy within atoms
3.4 Ionization energy and the shell model of the atom and occlusion
3.5 Electron affinity
3.6 Electronegativity: The tendency of an atom to attract electrons within a molecule.
3.7 Forces and Potential Energy in Molecules: Formation of Chemical Bonds
3.8 Ionic bonding
3.9 Covalent Bonds and Polar Covalent Bonds
3.10 Electron Pair Bonding and Lewis Structures of Molecules
3.11 Molecular Shape: Valence Shell Electron Pair Repulsion Theory
3.12 Oxidation number
3.13 Nomenclature of Inorganic Compounds

Chapter 4: Introduction to Quantum Mechanics
4.1 Introduction: Waves and Light
4.2 Evidence of energy quantization in atoms
4.3 Bohr Model: Predicting Discrete Energy Levels of an Atom
4.4 Evidence for wave-particle duality
4.5 Schrodinger equation
4.6 Quantum mechanics of the particle-in-a-box model
4.7 Deep Learning: Wave Functions of Particles in 2D and 3D Boxes

Chapter 5: Quantum Mechanics and Atomic Structure
5.1 Hydrogen Atom
5.2 Shell model of multielectron atoms
5.3 Stacking Principle and Electronic Configuration
5.4 Shells and the Periodic Table: Photoelectron Spectroscopy
5.5 Periodic properties and electronic structure

Chapter 6: Quantum Mechanics and Molecular Structure
6.1 Quantum Description of Chemical Bonding
6.2 Complete molecular orbitals for the simplest molecule: H₂+
6.3 Molecular orbital theory for H₂+ and linear combination approximation of atomic orbitals
6.4 Homonuclear Diatomic Molecules: Period 1 Atoms
6.5 Homogeneous? Diatomic Molecules: Period 2 Atoms
6.6 Heteronuclear diatomic molecules
6.7 Summary of the linear combination method of atomic orbitals and diatomic molecules
6.8 Atomic Bonding Theory and Electron Pair Bonding
6.9 Orbital Hybridization for Polyatomic Molecules
6.10 Predicting molecular structure and shape

Chapter 7 Bonding of Organic Molecules
7.1 Petroleum Refining and Hydrocarbons
7.2 Alkanes
7.3 Alkenes and Alkynes
7.4 Aromatic hydrocarbons
7.5 Fullerene
7.6 Functional groups and organic reactions
7.7 Pesticides and Medicines

Chapter 8: Bonding of Transition Metal Compounds and Coordination Complexes
8.1 Transition Metal Chemistry
8.2 Entering Coordination Chemistry
8.3 Structure of coordination complexes
8.4 Crystal field theory: optical and magnetic properties
8.5 Optical Properties and Spectrochemical Series
8.6 Coordination complex binding

Part 3: Kinetic Molecular Description of the States of Matter

Chapter 9 Gaseous State
9.1 Chemistry of Gases
9.2 Pressure and temperature of gases
9.3 Ideal Gas Law
9.4 Gas mixtures
9.5 Kinetic theory of gases
9.6 Real Gases: Intermolecular Forces
9.7 Deep Learning: Bunda Collisions and Velocity Processes

Chapter 10 Solids, Liquids, and Phase Transitions
10.1 Properties of gases, liquids, and solids: Description at the molecular level
10.2 Intermolecular Forces: Origins of Molecular Structure
10.3 Intermolecular forces in liquids
10.4 Phase equilibrium
10.5 Phase transition
10.6 Trademark

Chapter 11 Solutions
11.1 Composition of the solution
11.2 Properties of dissolved substances
11.3 Stoichiometry in Solutions: Acid-Base Titrations
11.4 Stoichiometry in solutions: Redox titrations
11.5 Phase Equilibrium of Solutions: Nonvolatile Substances
11.6 Phase Equilibrium of Solutions: Volatile Solutes
11.7 Colloidal suspension

Part 4 Equilibrium in Chemical Reactions

Chapter 12 Thermodynamic Processes and Thermochemistry
12.1 State, Condition, and Process
12.2 The First Law of Thermodynamics: Internal Energy, Work, and Heat
12.3 Heat capacity, calorimetry, and enthalpy
12.4 The First Law of Thermodynamics and Various Processes in Ideal Gases
12.5 Contribution of molecules to internal energy and heat capacity
12.6 Thermochemistry
12.7 Reversible processes in ideal gases
12.8 Deep Learning: Energy Distribution Between Molecules

Chapter 13 Spontaneous Processes and Thermodynamic Equilibrium
13.1 The nature of the voluntary process
13.2 Entropy and Spontaneity: A Molecular Statistical Interpretation
13.3 Entropy and Heat: Macroscopic Basis for the Second Law of Thermodynamics
13.4 Entropy Change in a Reversible Process
13.5 Entropy Change and Spontaneity
13.6 The Third Law of Thermodynamics
13.7 Gibbs free energy
13.8 Deep Learning: Carnot Cycles, Efficiency, and Entropy

Chapter 14 Chemical Equilibrium
14.1 The Nature of Chemical Equilibrium
14.2 Law of Mass Action
14.3 Thermodynamic description of equilibrium
14.4 Law of Mass Action for Simultaneously Associated Equilibria
14.5 Equilibrium Calculations for Gas-Phase Heterogeneous Reactions
14.6 Direction of Change in Chemical Reactions: An Experimental Explanation
14.7 Direction of Change in Chemical Reactions: A Thermodynamic Explanation
14.8 Partitioning of a Chemical Species Between Immiscible Phases: Extraction and Separation Processes

Chapter 15 Acid-Base Equilibrium
15.1 Classification of acids and bases
15.2 Properties of Acids and Bases in Aqueous Solutions: Bronsted-Lowry System
15.3 Strength of acids and bases
15.4 Equilibrium of weak acids and weak bases
15.5 Buffer solution
15.6 Acid-base titration curve
15.7 Diversity Assets
15.8 Organic Acids and Bases: Structure and Reactivity
15.9 Deep Learning: Accurate Calculation of Acid-Base Equilibria

Chapter 16 Solubility and Precipitation Equilibrium
16.1 The nature of solubility equilibrium
16.2 Ionic equilibrium between solids and solutions
16.3 Precipitation and solubility product
16.4 Effect of pH on solubility
16.5 Complex ions and solubility
16.6 Deep Learning: Selective Precipitation of Ions

Chapter 17 Electrochemistry
17.1 Electrochemical Cells
17.2 Cell potential and Gibbs free energy
17.3 Molecular Understanding of Electrochemical Processes
17.4 Effect of concentration and Nernst equation
17.5 Molecular Electrochemistry
17.6 Batteries and Fuel Cells
17.7 Corrosion and Corrosion Prevention
17.8 Electrometallurgy
17.9 Deep Learning: Electrolysis of Water and Aqueous Solutions

Part 5: Speed ​​of Chemistry and Physics Processes

Chapter 18: Chemical Reaction Rates
18.1 Chemical reaction rates
18.2 Rate Laws
18.3 Reaction Mechanism
18.4 Reaction Mechanisms and Rates
18.5 Temperature dependence of reaction rate
18.6 Molecular theory of single-step reactions
18.7 Solution phase reactions
18.8 Catalysis

Chapter 19 Nuclear Chemistry
19.1 Radiation
19.2 Nuclear Structure and Nuclear Decay Process
19.3 Mass-energy correlation
19.4 Kinetics of Radioactive Decay
19.5 Radiation in Biology and Medicine
19.6 Nuclear fission
19.7 Nuclear Fusion and Nucleosynthesis
19.8 Deep Learning: Nuclear Shell Model

Chapter 20 Molecular Spectroscopy and Photochemistry
20.1 Introduction to Molecular Spectroscopy
20.2 Experimental Methods in Molecular Spectroscopy
20.3 Rotational and vibrational spectroscopy
20.4 Nuclear Magnetic Resonance Spectroscopy
20.5 Electronic Spectroscopy and Excited-State Relaxation Processes
20.6 Introduction to Atmospheric Chemistry
20.7 Photosynthesis
20.8 Deep Learning: Einstein's Radiation Relations and Lasers

Part 6 Materials

Chapter 21 Structure and Bonding of Solids
21.1 Crystal symmetry and unit cell
21.2 Crystal structure
21.3 Coagulation in solids
21.4 Defects and Amorphous Solids
21.5 Deep Learning: Lattice Energy of Decisions

Chapter 22 Weapon Materials
22.1 Minerals: Natural inorganic substances
22.2 Properties of Ceramics
22.3 Silicate Ceramics
22.4 Non-silicate ceramics
22.5 Electrical Conduction of Materials
22.6 The Belt Theory of Conduction
22.7 Semiconductors
22.8 Pigments and Phosphors: Optical Displays

Chapter 23 Polymer Materials and Soft Solids
23.1 Polymerization reactions of synthetic polymers
23.2 Applications of Synthetic Polymers
23.3 LCD
23.4 Natural polymers

supplement