General, Organic, and Biological Chemistry

Laura D. Frost is a Professor of Chemistry at Florida Gulf Coast University. She received her bachelor’s degree in chemistry from Kutztown University and a Ph.D. in chemistry with a biophysical focus from the University of Pennsylvania. Professor Frost is actively engaged in the teaching and learning of chemistry and uses a guided inquiry approach in her classes. Dr. Frost is a member of the American Chemical Society and its Chemical Education division and the Biophysical Society. In 2007, she was honored with the Regent’s Award for the Scholarship of Teaching and Learning by the University System of Georgia and was inducted into the Regent’s Hall of Fame for Teaching Excellence. She is an advocate for increased student learning in science, technology, engineering, and mathematics (STEM) disciplines using guided inquiry and has spoken at numerous conferences and workshops on this topic. Todd S. Deal received his B.S. degree in chemistry in 1986 from Georgia Southern College (now University) in Statesboro, Georgia, and his Ph.D. in chemistry in 1990 from The Ohio State University. He joined the faculty of his undergraduate alma mater in 1992, where he currently serves as Director of the Office of Student Leadership and Civic Engagement. Professor Deal has taught chemistry to allied health and preprofessional students for 20 years. In 1994, he was selected Professor of the Year by the students at Georgia Southern University. Professor Deal is also the recipient of the Allen E. Paulson College of Science and Technology’s Award for Excellence in Teaching (2003), the Georgia Southern University Award for Excellence in Contributions to Instruction (2003), and the Allen E. Paulson College of Science and Technology’s Award for Excellence in Service (2006). Karen Timberlake is Professor Emerita of chemistry at Los Angeles Valley College, where she taught chemistry for allied health and preparatory chemistry for 36 years. Professor Timberlake has been writing chemistry textbooks for 33 years. She is known for her strategic use of pedagogical tools that promote student success in chemistry and the application of chemistry to real-life situations. More than one million students have learned chemistry using texts, laboratory manuals, and study guides written by Karen Timberlake.

Chapter 1: Chemistry Basics: Matter and Measurement

1.1 Classifying Matter: Mixture or Pure Substance

1.2 Elements, Compounds, and the Periodic Table

1.3 Math Counts

1.4 Matter: The “Stuff” of Chemistry

1.5 Measuring Matter

1.6 How Matter Changes

 

Chapter 2: Atoms and Radioactivity

2.1 Atoms and Their Components

2.2 Atomic Number and Mass Number

2.3 Isotopes and Atomic Mass

2.4 Radioactivity and Radioisotopes

2.5 Nuclear Equations and Radioactive Decay

2.6 Radiation Units and Half-Lives

2.7 Medical Applications for Radioisotopes

 

Chapter 3: Compounds: Putting Particles Together

3.1 Electron Arrangements and the Octet Rule

3.2 In Search of an Octet, Part 1: Ion Formation

3.3 Ionic Compounds–Electron Give and Take

3.4 In Search of an Octet, Part 2: Covalent Bonding

3.5 The Mole: Counting Atoms and Compounds

3.6 Getting Covalent Compounds into Shape

3.7 Electronegativity and Molecular Polarity

 

Chapter 4: Introduction to Organic Compounds

4.1 Alkanes: The Simplest Organic Compounds

4.2 Representing the Structures of Organic Compounds

4.3 Families of Organic Compounds–Functional Groups

4.4 Nomenclature of Simple Alkanes

4.5 Isomerism in Organic Compounds

 

Chapter 5: Chemical Reactions

5.1 Thermodynamics

5.2 Chemical Reactions: Kinetics

5.3 Overview of Chemical Reactions

5.4 Oxidation and Reduction

5.5 Organic Reactions: Condensation and Hydrolysis

5.6 Organic Addition Reactions to Alkenes

 

Chapter 6: Carbohydrates: Life’s Sweet Molecules

6.1 Classes of Carbohydrates

6.2 Functional Groups in Monosaccharides

6.3 Stereochemistry in Monosaccharides

6.4 Reactions of Monosaccharides

6.5 Disaccharides

6.6 Polysaccharides

6.7 Carbohydrates and Blood

 

Chapter 7: What’s the Attraction? State Changes, Solubility, and Lipids

7.1 Types of Attractive Forces

7.2 Liquids and Solids: Attractive Forces are Everywhere

7.3 Attractive Forces and Solubility

7.4 Gases: Attractive Forces are Limited

7.5 Dietary Lipids and Trans Fats

7.6 Attractive Forces and the Cell Membrane

 

Chapter 8: Solution Chemistry: How Sweet is Your Tea?

8.1 Solutions are Mixtures

8.2 Formation of Solutions

8.3 Chemical Equations for Solution Formation

8.4 Concentrations

8.5 Dilution

8.6 Osmosis and Diffusion

8.7 Transport Across Cell Membranes

 

Chapter 9: Acids, Bases, and Buffers in the Body

9.1 Acids and Bases- Definitions

9.2 Strong Acids and Bases

9.3 Chemical Equilibrium

9.4 Weak Acids and Bases

9.5 pH and the pH Scale

9.6 pKa

9.7 Amino Acids: Common Biological Weak Acids

9.8 Buffers and Blood: The Bicarbonate Buffer System

 

Chapter 10: Proteins: Workers of the Cell

10.1 Amino Acids-A Second Look

10.2 Protein Formation

10.3 The Three-Dimensional

Structure of Proteins

10.4 Denaturation of Proteins

10.5 Protein Functions

10.6 Enzymes—Life’s Catalysts

10.7 Factors That Affect Enzyme Activity

 

Chapter 11: Nucleic Acids: Big Molecules with a Big Role

10.1 Components of Nucleic Acids

10.2 Nucleic Acid Formation

10.3 DNA

10.4 RNA and Protein Synthesis

11.5 Putting It Together:

The Genetic Code and

Protein Synthesis

11.6 Genetic Mutations

11.7 Viruses

11.8 Recombinant DNA Technology

 

Chapter 12: Food as Fuel: A Metabolic Overview

12.1 How Metabolism Works

12.2 Metabolically Relevant Nucleotides

12.3 Digestion—From Food Molecules to Hydrolysis

Products

12.4 Glycolysis—From Hydrolysis Products to Common

Metabolites

12.5 The Citric Acid Cycle—Central Processing

12.6 Electron Transport and Oxidative

Phosphorylation

12.7 ATP Production

12.8 Other Fuel Choices