WebAssign Companion to Silberberg - Chemistry 6/e 1st edition

Access is contingent on use of this textbook in the instructor's classroom.

• Chapter T: WebAssign Answer Templates and Tutorials
  • T: WebAssign Answer Templates and Tutorials
  
  
• Chapter 1: Introduction to Chemistry
  • 1.1: The Fundamentals of Chemistry
  • 1.2: The Origins of Chemistry
  • 1.3: The Scientific Method
  • 1.4: Solving Chemistry Problems
  • 1.5: Measurement and Units
  • 1.6: Measurement Uncertainty
  • 1: Concept Mastery
  • 1: Exercises
  • 1: Stand Alone Tutorials
  
  
• Chapter 2: Matter
  • 2.1: Classification of Matter
  • 2.2: Development of Atomic Theory
  • 2.3: Dalton's Atomic Theory
  • 2.4: Development of the Nuclear Atom Model
  • 2.5: Modern Atomic Theory
  • 2.6: Elements
  • 2.7: Formation of Compounds
  • 2.8: Compounds: Formulas, Nomenclature, and Mass
  • 2.9: Mixtures
  • 2: Concept Mastery
  • 2: Exercises
  • 2: Stand Alone Tutorials
  
  
• Chapter 3: Stoichiometry
  • 3.1: Converting Between Mass and Moles
  • 3.2: Obtaining an Unknown Compound's Formula
  • 3.3: Chemical Equations
  • 3.4: Determining the Amount of Reactant and Product
  • 3.5: Solution Stoichiometry
  • 3: Concept Mastery
  • 3: Exercises
  • 3: Stand Alone Tutorials
  
  
• Chapter 4: Chemical Reactions
  • 4.1: Water as a Solvent
  • 4.2: Using Equations to Represent Aqueous Ionic Reactions
  • 4.3: Precipitation Reactions
  • 4.4: Acid-Base Reactions
  • 4.5: Redox Reactions
  • 4.6: Classification of Redox Reactions
  • 4.7: Reversible Reactions
  • 4: Concept Mastery
  • 4: Exercises
  • 4: Stand Alone Tutorials
  
  
• Chapter 5: Gases
  • 5.1: Properties of Gases
  • 5.2: Pressure
  • 5.3: The Empirical Gas Laws
  • 5.4: Ideal Gases
  • 5.5: The Kinetic-Molecular Theory
  • 5.6: Non-ideal Gases
  • 5: Concept Mastery
  • 5: Exercises
  • 5: Stand Alone Tutorials
  
  
• Chapter 6: Thermochemistry
  • 6.1: Energy
  • 6.2: Enthalpy
  • 6.3: Calorimetry
  • 6.4: Thermochemical Equations and Stoichiometry
  • 6.5: Hess's Law
  • 6.6: Standard Enthalpies of Formation and Reaction
  • 6: Concept Mastery
  • 6: Exercises
  • 6: Stand Alone Tutorials
  
  
• Chapter 7: Quantum Theory
  • 7.1: Light
  • 7.2: Atomic Structure
  • 7.3: The Wave and Particle Nature of Matter and Energy
  • 7.4: Quantum Mechanics
  • 7: Concept Mastery
  • 7: Exercises
  • 7: Stand Alone Tutorials
  
  
• Chapter 8: Electron Configuration and Periodic Trends
  • 8.1: Properties of Many-Electron Atoms
  • 8.2: Quantum Mechanics and the Periodic Table
  • 8.3: Periodic Trends
  • 8.4: Trends in Chemical and Physical Properties
  • 8: Concept Mastery
  • 8: Exercises
  • 8: Stand Alone Tutorials
  
  
• Chapter 9: Bonding
  • 9.1: Overview of Bonding
  • 9.2: Ionic Bonding
  • 9.3: Covalent Bonding
  • 9.4: Bond Energy
  • 9.5: Electronegativity and Polarity
  • 9.6: Overview of Metallic Bonding
  • 9: Concept Mastery
  • 9: Exercises
  • 9: Stand Alone Tutorials
  
  
• Chapter 10: Molecular and Electron Domain Geometry
  • 10.1: Lewis Structures
  • 10.2: VSEPR Theory
  • 10.3: Molecular Polarity
  • 10: Concept Mastery
  • 10: Exercises
  • 10: Stand Alone Tutorials
  
  
• Chapter 11: Covalent Bonding
  • 11.1: Valence Bond Theory and Hybridization of Orbitals
  • 11.2: Sigma and Pi Bonding
  • 11.3: Molecular Orbitals and Delocalization
  • 11: Concept Mastery
  • 11: Exercises
  • 11: Stand Alone Tutorials
  
  
• Chapter 12: Liquids and Solids
  • 12.1: Introduction to Physical States and Phase Transitions
  • 12.2: Quantifying Properties of Phase Transitions
  • 12.3: Intermolecular Forces
  • 12.4: Characteristics of Liquids
  • 12.5: Properties of Water
  • 12.6: Characteristics of Solids
  • 12.7: Materials Science
  • 12: Concept Mastery
  • 12: Exercises
  • 12: Stand Alone Tutorials
  
  
• Chapter 13: Solution Chemistry
  • 13.1: Solution Classification
  • 13.2: Biological Macromolecules and Their Intermolecular Forces
  • 13.3: Solubility on the Molecular Level
  • 13.4: Effects of Temperature and Pressure on Solubility
  • 13.5: Concentration Units
  • 13.6: Colligative Properties
  • 13.7: Colloids
  • 13: Concept Mastery
  • 13: Exercises
  • 13: Stand Alone Tutorials
  
  
• Chapter 14: Periodic Trends
  • 14.1: Hydrogen Chemistry
  • 14.2: Periodic Trends of the Elements in Period 2
  • 14.3: The Alkali Metals in Group 1
  • 14.4: The Alkaline Earth Metals in Group 2
  • 14.5: The Boron Family in Group 13
  • 14.6: The Carbon Family in Group 14
  • 14.7: The Nitrogen Family in Group 15
  • 14.8: The Oxygen Family in Group 16
  • 14.9: The Halogens in Group 17
  • 14.10: The Noble Gases in Group 18
  • 14: Concept Mastery
  • 14: Exercises
  • 14: Stand Alone Tutorials
  
  
• Chapter 15: Organic Chemistry
  • 15.1: Introduction to Organic Chemistry
  • 15.2: Hydrocarbons
  • 15.3: Classification of Organic Reactions
  • 15.4: Functional Groups
  • 15.5: Synthetic Macromolecules
  • 15.6: Biological Macromolecules
  • 15: Concept Mastery
  • 15: Exercises
  • 15: Stand Alone Tutorials
  
  
• Chapter 16: Kinetics
  • 16.1: Rates of Reactions
  • 16.2: Reaction Rate Expressions
  • 16.3: Rate Laws
  • 16.4: Integrated Rate Laws
  • 16.5: Collision and Transition State Theories
  • 16.6: Reaction Mechanisms
  • 16.7: Catalysts
  • 16: Concept Mastery
  • 16: Exercises
  • 16: Stand Alone Tutorials
  
  
• Chapter 17: Equilibrium
  • 17.1: Introduction to Equilibrium
  • 17.2: The Reaction Quotient
  • 17.3: Expressing Equilibria in Terms of Pressure
  • 17.4: Determining Reaction Direction with the Equilibrium Constant and Reaction Quotient
  • 17.5: Solving Equilibrium Problems
  • 17.6: Le Châtelier's Principle
  • 17: Concept Mastery
  • 17: Exercises
  • 17: Stand Alone Tutorials
  
  
• Chapter 18: Equilibria: Acid-Base
  • 18.1: Acids and Bases in Aqueous Solution
  • 18.2: Autoionization of Water
  • 18.3: Brønsted-Lowry Acids and Bases
  • 18.4: Weak Acids
  • 18.5: Weak Bases
  • 18.6: Effect of Molecular Structure on Acid Strength
  • 18.7: Acidic and Basic Salt Solutions
  • 18.8: The Leveling Effect
  • 18.9: Lewis Acids and Bases
  • 18: Concept Mastery
  • 18: Exercises
  • 18: Stand Alone Tutorials
  
  
• Chapter 19: Aqueous Ionic Equilibrium Systems
  • 19.1: Buffers
  • 19.2: Acid-Base Titrations
  • 19.3: Equilibria Involving Slightly Soluble Ionic Compounds
  • 19.4: Equilibria of Complex Ions
  • 19: Concept Mastery
  • 19: Exercises
  • 19: Stand Alone Tutorials
  
  
• Chapter 20: Thermodynamics
  • 20.1: Predicting Spontaneity
  • 20.2: Entropy Changes
  • 20.3: Free Energy and Work
  • 20.4: Relating Free Energy to the Equilibrium Constant
  • 20: Concept Mastery
  • 20: Exercises
  • 20: Stand Alone Tutorials
  
  
• Chapter 21: Electrochemistry
  • 21.1: Redox Reactions and Their Use in Electrochemical Cells
  • 21.2: Voltaic Cells
  • 21.3: Cell Potential
  • 21.4: Free Energy, Work, and Concentration Cells
  • 21.5: Batteries
  • 21.6: Corrosion
  • 21.7: Electrolytic Cells
  • 21: Concept Mastery
  • 21: Exercises
  • 21: Stand Alone Tutorials
  
  
• Chapter 22: The Elements in Nature and Industrial Applications
  • 22.1: Natural Abundance of Elements
  • 22.2: Environmental Cycles of Elements
  • 22.3: Metallurgy
  • 22.4: Isolation and Uses of Some Elements
  • 22.5: Industrial Production of Sulfuric Acid and Chlorine
  • 22: Concept Mastery
  • 22: Exercises
  • 22: Stand Alone Tutorials
  
  
• Chapter 23: Transition Elements and Coordination Chemistry
  • 23.1: The Transition Elements
  • 23.2: The Lanthanides and Actinides
  • 23.3: Coordination Chemistry
  • 23.4: Valence Bond and Crystal Field Theories
  • 23: Concept Mastery
  • 23: Exercises
  • 23: Stand Alone Tutorials
  
  
• Chapter 24: Nuclear Chemistry
  • 24.1: Nuclear Decay and Stability
  • 24.2: The Kinetics of Nuclear Change
  • 24.3: Nuclear Transmutation
  • 24.4: Effects of Radiation
  • 24.5: Uses of Radioisotopes
  • 24.6: Nuclear Binding Energy
  • 24.7: Nuclear Fission and Fusion
  • 24: Concept Mastery
  • 24: Exercises
  • 24: Stand Alone Tutorials
  
  
• Chapter FE: Final Exam Questions
  • FE: Final Exam Questions
  • FE: Stand Alone Tutorials