WebAssign Companion to Ebbing et al. - General Chemistry 10/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 Study of Chemistry
  • 1.2: The Scientific Method
  • 1.3: Law of Conservation of Mass
  • 1.4: Physical and Chemical Properties of Matter
  • 1.5: Measurement and Precision
  • 1.6: SI Unit Conversions
  • 1.7: Derived Unit Conversions
  • 1.8: Dimensional Analysis
  • 1: Concept Mastery
  • 1: Exercises
  • 1: Stand Alone Tutorials
  
  
• Chapter 2: Atomic Structure and the Periodic Table
  • 2.1: Atomic Theory
  • 2.2: Atomic Structure
  • 2.3: Mass, Subatomic Particles, and Isotopes
  • 2.4: Average Atomic Mass
  • 2.5: The Periodic Table
  • 2.6: Ionic and Molecular Formulas
  • 2.7: Overview of Organic Chemistry
  • 2.8: Chemical Nomenclature
  • 2.9: Writing Chemical Equations
  • 2.10: Balancing Chemical Equations
  • 2: Concept Mastery
  • 2: Exercises
  • 2: Stand Alone Tutorials
  
  
• Chapter 3: Stoichiometry
  • 3.1: Molecular Mass vs. Formula Mass
  • 3.2: The Mole
  • 3.3: Percent Composition
  • 3.4: Elemental Analysis
  • 3.5: Obtaining an Unknown Compound's Formula
  • 3.6: Stoichiometry
  • 3.7: Determining the Amount of Reactant and Product
  • 3.8: Limiting and Excess Reagents
  • 3: Concept Mastery
  • 3: Exercises
  • 3: Stand Alone Tutorials
  
  
• Chapter 4: Chemical Reactions
  • 4.1: Electrolytes, Nonelectrolytes, and Solubility Guidelines
  • 4.2: Molecular, Complete Ionic, and Net Ionic Equations
  • 4.3: Precipitation Reactions
  • 4.4: Acid-Base Reactions
  • 4.5: Redox Reactions
  • 4.6: Simple Redox Reactions
  • 4.7: Molarity
  • 4.8: Dilutions
  • 4.9: Separating Ions with Precipitation
  • 4.10: Acid-Base Titrations
  • 4: Concept Mastery
  • 4: Exercises
  • 4: Stand Alone Tutorials
  
  
• Chapter 5: Gases
  • 5.1: Gas Pressure
  • 5.2: The Gas Laws
  • 5.3: Ideal Gases
  • 5.4: Gas Stoichiometry
  • 5.5: Mixtures of Gases
  • 5.6: The Kinetic Molecular Theory
  • 5.7: Molecular Effusion and Diffusion
  • 5.8: Non-Ideal Gases
  • 5: Concept Mastery
  • 5: Exercises
  • 5: Stand Alone Tutorials
  
  
• Chapter 6: Thermochemistry
  • 6.1: Energy
  • 6.2: The First Law of Thermodynamics
  • 6.3: Enthalpies of Reaction
  • 6.4: Equations with Enthalpy of Reaction
  • 6.5: Stoichiometry and Enthalpies of Reaction
  • 6.6: Calorimetry
  • 6.7: Hess's Law
  • 6.8: Standard Enthalpies of Formation and Reaction
  • 6.9: Fuels
  • 6: Concept Mastery
  • 6: Exercises
  • 6: Stand Alone Tutorials
  
  
• Chapter 7: Quantum Theory
  • 7.1: Light
  • 7.2: Quantization of Energy
  • 7.3: The Bohr Model
  • 7.4: Quantum Mechanics
  • 7.5: Quantum Numbers and Atomic Orbital Shapes
  • 7: Concept Mastery
  • 7: Exercises
  • 7: Stand Alone Tutorials
  
  
• Chapter 8: Electron Configurations and Periodic Trends
  • 8.1: The Pauli Exclusion Principle
  • 8.2: The Aufbau Principle
  • 8.3: Electron Configurations and the Periodic Table
  • 8.4: Atomic Orbital Diagrams and Hund's Rule
  • 8.5: The Development of the Periodic Table
  • 8.6: Periodic Trends
  • 8.7: Periodic Trends of Main-Group Elements
  • 8: Concept Mastery
  • 8: Exercises
  • 8: Stand Alone Tutorials
  
  
• Chapter 9: Bonding: Ionic and Covalent
  • 9.1: Bonding in Ionic Compounds
  • 9.2: Electron Configurations of Ions
  • 9.3: Ion Size
  • 9.4: Bonding in Covalent Compounds
  • 9.5: Polarity and Electronegativity
  • 9.6: Drawing Lewis Structures
  • 9.7: Delocalization and Resonance
  • 9.8: Octet Rule Exceptions
  • 9.9: Formal Charge
  • 9.10: Bond Length and Bond Order
  • 9.11: Bond Enthalpy
  • 9: Concept Mastery
  • 9: Exercises
  • 9: Stand Alone Tutorials
  
  
• Chapter 10: Molecular Geometry and Bonding
  • 10.1: VSEPR Theory
  • 10.2: Polarity and Molecular Geometry
  • 10.3: Valence Bond Theory and Hybridization
  • 10.4: Sigma and Pi Bonding
  • 10.5: Molecular Orbital Theory
  • 10.6: Electron Configurations of Diatomic Molecules
  • 10.7: Molecular Orbitals and Delocalization
  • 10: Concept Mastery
  • 10: Exercises
  • 10: Stand Alone Tutorials
  
  
• Chapter 11: Liquids and Solids
  • 11.1: Properties of the States-of-Matter
  • 11.2: Phase Changes
  • 11.3: Phase Diagrams
  • 11.4: Characteristics of Liquids
  • 11.5: Intermolecular Forces
  • 11.6: Types of Solids
  • 11.7: Crystalline Solids
  • 11.8: Structures of Crystalline Solids
  • 11.9: Unit Cell Calculations
  • 11.10: X-Ray Diffraction
  • 11: Concept Mastery
  • 11: Exercises
  • 11: Stand Alone Tutorials
  
  
• Chapter 12: Solution Chemistry
  • 12.1: Classifications of Solids
  • 12.2: Solubility on the Molecular Level
  • 12.3: Factors Affecting Solubility
  • 12.4: Concentration Units
  • 12.5: Vapor Pressure
  • 12.6: Boiling-Point Elevation and Freezing-Point Depression
  • 12.7: Osmosis
  • 12.8: Colligative Properties
  • 12.9: Colloids
  • 12: Concept Mastery
  • 12: Exercises
  • 12: Stand Alone Tutorials
  
  
• Chapter 13: Kinetics
  • 13.1: Introduction to Reaction Rates
  • 13.2: Experiments to Determine Reaction Rates
  • 13.3: Effect of Concentration on Reaction Rate
  • 13.4: Integrated Rate Laws
  • 13.5: Effect of Temperature on Reaction Rate and Theories of Reaction Rates
  • 13.6: Mathematical Expressions for the Dependence of the Rate Constant on Temperature
  • 13.7: Elementary Reactions
  • 13.8: Rate Laws
  • 13.9: Catalysts
  • 13: Concept Mastery
  • 13: Exercises
  • 13: Stand Alone Tutorials
  
  
• Chapter 14: Equilibrium
  • 14.1: Introduction to Equilibrium
  • 14.2: The Equilibrium Constant and Expression
  • 14.3: Heterogeneous and Homogeneous Equilibria
  • 14.4: Understanding the Equilibrium Constant
  • 14.5: The Reaction Quotient
  • 14.6: Determining Equilibrium Concentrations
  • 14.7: Le ChâtelierÕs Principle
  • 14.8: Effect of Temperature and Pressure Changes on Equilibrium
  • 14.9: Effect of a Catalyst on Equilibrium
  • 14: Concept Mastery
  • 14: Exercises
  • 14: Stand Alone Tutorials
  
  
• Chapter 15: Acids and Bases
  • 15.1: Arrhenius Acids and Bases
  • 15.2: Brønsted—Lowry Acids and Bases
  • 15.3: Lewis Acids and Bases
  • 15.4: Comparing Acid and Base Strength
  • 15.5: Effect of Molecular Structure on Acid Strength
  • 15.6: Autoionization of Water
  • 15.7: Strong Acids and Bases
  • 15.8: pH and pOH
  • 15: Concept Mastery
  • 15: Exercises
  • 15: Stand Alone Tutorials
  
  
• Chapter 16: Equilibria: Acid-Base
  • 16.1: Acid Dissociation Equilibria
  • 16.2: Diprotic and Polyprotic Acids
  • 16.3: Base Dissociation Equilibria
  • 16.4: Acidic and Basic Salt Solutions
  • 16.5: The Common-Ion Effect
  • 16.6: Buffered Solutions
  • 16.7: Acid-Base Titrations
  • 16: Concept Mastery
  • 16: Exercises
  • 16: Stand Alone Tutorials
  
  
• Chapter 17: Equilibria: Solubility and Complex-Ion
  • 17.1: The Solubility Product Constant
  • 17.2: Equilibria Involving Slightly Soluble Ionic Compounds
  • 17.3: Predicting Precipitation and Fractional Precipitation
  • 17.4: Dependence of Solubility on pH
  • 17.5: Formation Constants and Amphoteric Hydroxides
  • 17.6: Solubility in the Presence of Complex Ions
  • 17.7: Qualitative Analysis for the Presence of Metal Ions
  • 17: Concept Mastery
  • 17: Exercises
  • 17: Stand Alone Tutorials
  
  
• Chapter 18: Thermodynamics
  • 18.1: The First Law of Thermodynamics
  • 18.2: The Second Law of Thermodynamics
  • 18.3: The Third Law of Thermodynamics
  • 18.4: Relating Free Energy to Spontaneity
  • 18.5: Free Energy and Work
  • 18.6: Relating Free Energy to the Equilibrium Constant
  • 18.7: Effect of Temperature on Free Energy
  • 18: Concept Mastery
  • 18: Exercises
  • 18: Stand Alone Tutorials
  
  
• Chapter 19: Electrochemistry
  • 19.1: Balancing Redox Reactions in Acidic or Basic Solution
  • 19.2: Galvanic Cells
  • 19.3: Notation for Galvanic Cells
  • 19.4: Cell Potential and Work
  • 19.5: Standard Cell Potentials and Standard Electrode Potentials
  • 19.6: Cell Potential and the Equilibrium Constant
  • 19.7: Effect of Concentration on Cell Potential
  • 19.8: Industrial Galvanic Cells
  • 19.9: Electrolysis of Molten Salts
  • 19.10: Electrolytic Cells
  • 19.11: Stoichiometry and Electrolysis
  • 19: Concept Mastery
  • 19: Exercises
  • 19: Stand Alone Tutorials
  
  
• Chapter 20: Nuclear Chemistry
  • 20.1: Radioactive Decay
  • 20.2: Nuclear Transmutation
  • 20.3: Effects of Radiation on Biological Systems
  • 20.4: Rate of Radioactive Decay and Half-Life
  • 20.5: Uses for Radioisotopes
  • 20.6: Nuclear Binding Energy
  • 20.7: Nuclear Fission and Fusion
  • 20: Concept Mastery
  • 20: Exercises
  • 20: Stand Alone Tutorials
  
  
• Chapter 21: The Main-Group Elements
  • 21.1: Overview of the Main-Group Elements
  • 21.2: Metals
  • 21.3: Metallic Bonding
  • 21.4: The Alkali Metals in Group 1
  • 21.5: The Alkaline Earth Metals in Group 2
  • 21.6: The Metals in Group 13 and Group 14
  • 21.7: Hydrogen
  • 21.8: The Carbon Family in Group 14
  • 21.9: The Nitrogen Family in Group 15
  • 21.10: The Oxygen Family in Group 16
  • 21.11: The Halogens in Group 17
  • 21.12: The Noble Gases in Group 18
  • 21: Concept Mastery
  • 21: Exercises
  • 21: Stand Alone Tutorials
  
  
• Chapter 22: Transition Elements and Coordination Chemistry
  • 22.1: Periodic Trends of the Transition Elements
  • 22.2: Chromium and Copper
  • 22.3: Coordination Compounds
  • 22.4: Coordination Chemistry Nomenclature
  • 22.5: Structures and Isomers of Coordination Compounds
  • 22.6: Valence Bond Theory in Coordination Chemistry
  • 22.7: Crystal Field Theory
  • 22: Concept Mastery
  • 22: Exercises
  • 22: Stand Alone Tutorials
  
  
• Chapter 23: Organic Chemistry
  • 23.1: Introduction to Organic Chemistry
  • 23.2: Acyclic and Cyclic Saturated Hydrocarbons
  • 23.3: Unsaturated Hydrocarbons
  • 23.4: Aromaticity
  • 23.5: Organic Chemistry Nomenclature
  • 23.6: Oxygen-Containing Organic Compounds
  • 23.7: Nitrogen-Containing Organic Compounds
  • 23: Concept Mastery
  • 23: Exercises
  • 23: Stand Alone Tutorials
  
  
• Chapter 24: Polymeric Solids
  • 24.1: Organic Polymer Synthesis
  • 24.2: Polymers with Electrical Conductivity
  • 24.3: Proteins
  • 24.4: Nucleic Acids
  • 24: Concept Mastery
  • 24: Exercises
  • 24: Stand Alone Tutorials
  
  
• Chapter FE: Final Exam Questions
  • FE: Final Exam Questions
  • FE: Stand Alone Tutorials