Anne E. Marteel-Parrish, Martin A. Abraham
Green Chemistry and Engineering (eBook, ePUB)
A Pathway to Sustainability
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Anne E. Marteel-Parrish, Martin A. Abraham
Green Chemistry and Engineering (eBook, ePUB)
A Pathway to Sustainability
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Promotes a green approach to chemistry and chemical engineering for a sustainable planet With this text as their guide, students will gain a new outlook on chemistry and engineering. The text fully covers introductory concepts in general, organic, inorganic, and analytical chemistry as well as biochemistry. At the same time, it integrates such concepts as greenhouse gas potential, alternative and renewable energy, solvent selection and recovery, and ecotoxicity. As a result, students learn how to design chemical products and processes that are sustainable and environmentally friendly. Green…mehr
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Promotes a green approach to chemistry and chemical engineering for a sustainable planet With this text as their guide, students will gain a new outlook on chemistry and engineering. The text fully covers introductory concepts in general, organic, inorganic, and analytical chemistry as well as biochemistry. At the same time, it integrates such concepts as greenhouse gas potential, alternative and renewable energy, solvent selection and recovery, and ecotoxicity. As a result, students learn how to design chemical products and processes that are sustainable and environmentally friendly. Green Chemistry and Engineering presents the green approach as an essential tool for tackling problems in chemistry. A novel feature of the text is its integration of introductory engineering concepts, making it easier for students to move from fundamental science to applications. Throughout this text, the authors integrate several features to help students understand and apply basic concepts in general chemistry as well as green chemistry, including: * Comparisons of the environmental impact of traditional chemistry approaches with green chemistry approaches * Analyses of chemical processes in the context of life-cycle principles, demonstrating how chemistry fits within the complex supply chain * Applications of green chemistry that are relevant to students' lives and professional aspirations * Examples of successful green chemistry endeavors, including Presidential Green Chemistry Challenge winners * Case studies that encourage students to use their critical thinking skills to devise green chemistry solutions Upon completing this text, students will come to understand that chemistry is not antithetical to sustainability, but rather, with the application of green principles, chemistry is the means to a sustainable planet.
Produktdetails
- Produktdetails
- Verlag: John Wiley & Sons
- Seitenzahl: 376
- Erscheinungstermin: 10. Oktober 2013
- Englisch
- ISBN-13: 9781118720264
- Artikelnr.: 39681457
- Verlag: John Wiley & Sons
- Seitenzahl: 376
- Erscheinungstermin: 10. Oktober 2013
- Englisch
- ISBN-13: 9781118720264
- Artikelnr.: 39681457
ANNE E. MARTEEL-PARRISH, PhD, is Chair of the Chemistry Department at Washington College, in Maryland, and the inaugural holder of the college's Frank J. Creegan Chair in Green Chemistry. Among her honors, Dr. Marteel-Parrish is the recipient of the American Chemical Society's Committee on Environmental Improvement Award for Incorporating Sustainability into Chemistry Education. MARTIN A. ABRAHAM, PhD, is Professor of Chemical Engineering and Founding Dean of the College of Science, Technology, Engineering, and Mathematics at Youngstown State University. A Fellow of the American Chemical Society and the American Institute of Chemical Engineers, Dr. Abraham maintains an active research program in reaction engineering and catalysis. He also serves as Editor for the AIChE's quarterly journal Environmental Progress and Sustainable Energy.
Preface Chapter 1: Understanding the Issues 1 A brief history of chemistry 2 Twenty-first century chemistry, aka Green Chemistry 3 The layout of the book Chapter 2: Principles of Green Chemistry and Green Engineering 1 Introduction 2 Green Chemistry 3 Green Engineering 4 Sustainability Chapter 3: Chemistry as an Underlying Force in Ecosystem Interactions 1 Nature and the environment 2 Pollution Prevention 3 Ecotoxicology 4 Environmental assessment analysis 5 What can YOU do to make a difference? Chapter 4: Matter: The Heart of Green Chemistry 1 Matter: definition, classification, and the periodic table 2 The atomic structure 3 The three states of matter 4 Molecular and ionic compounds 5 Chemical reactions 6 Mixtures, acids, and bases Chapter 5: Chemical Reactions 1 Definition of chemical reactions and balancing of chemical equations 2 Chemical reactions and quantities of reactants and products 3 Patterns of chemical reactions 4 Effectiveness and efficiency of chemical reactions-Yield vs atom Chapter 6: Kinetics, Catalysis, and Reaction Engineering 1 Basic concept of rate 2 Role of industrial and biological catalysts 3 Reaction engineering 4 Summary Chapter 7: Thermodynamics, Separations and Equilibrium 1 Ideal gases 2 The first law of thermodynamics 3 Ideal gas calculations 4 Entropy and the second law of thermodynamics 5 Real gas properties 6 The phase diagram 7 Equilibrium 8 Solubility of a gas in a liquid 9 Solubility of a solid in a liquid 10 Summary Chapter 8: Renewable Materials 1 Introduction 2 Renewable feedstocks 3 Applications of renewable materials 4 Concluding thoughts Chapter 9: Current and Future State of Energy Production and Consumption 1 Introduction 2 Basic thermodynamic functions and applications 3 Other chemical processes for energy transfer 4 Renewable sources of energy in the 21st century and beyond 5 Concluding thoughts about sources of energy and their future Chapter 10: The Economics of Green and Sustainable Chemistry (Michael Gonzales) 1 Introduction 2 Chemical manufacturing and economic theory 3 The economic impact of green chemistry 4 Business strategies regarding application of green chemistry 5 Incorporation of green chemistry in process design for sustainability 6 Case studies demonstrating the economic benefits of green chemistry and design 7 Summary Chapter 11: Green Chemistry and Toxicology (Dale E Johnson and Grace L Anderson) 1 Introduction 2 Fundamental principles of toxicology 3 Identifying chemicals of concern 4 Toxicology data 5 Computational Toxicology and green chemistry 6 Applications of toxicology into green chemistry initiatives 7 Future perspectives
Preface xiii 1 UNDERSTANDING THE ISSUES 1 1.1 A Brief History of Chemistry
1 1.1.1 Fermentation: An Ancient Chemical Process 2 1.1.2 The Advent of
Modern Chemistry 2 1.1.3 Chemistry in the 20th Century: The Growth of
Modern Processes 2 1.1.4 Risks of Chemicals in the Environment 6 1.1.5
Regulations: Controlling Chemical Processes 11 1.2 Twenty-first Century
Chemistry, aka Green Chemistry 13 1.2.1 Green chemistry and Pollution
Prevention 13 1.2.2 Sustainability 14 1.3 Layout of the Book 18 References
19 2 PRINCIPLES OF GREEN CHEMISTRY AND GREEN ENGINEERING 21 2.1
Introduction 21 2.2 Green Chemistry 23 2.2.1 Definition 23 2.2.2 Principles
of Green Chemistry and Examples 24 2.2.3 Presidential Green Chemistry
Challenge Awards 31 2.3 Green Engineering 34 2.3.1 Definition 34 2.3.2
Principles of Green Engineering 35 2.4 Sustainability 38 References 41 3
CHEMISTRY AS AN UNDERLYING FORCE IN ECOSYSTEM INTERACTIONS 43 3.1 Nature
and the Environment 44 3.1.1 Air and the Atmosphere (Outdoor and Indoor
Pollution) 44 3.1.2 Water (Water Pollutants, Issues Associated with
Nonpotable Drinking Water) 52 3.1.3 Chemistry of the Land 53 3.1.4 Energy
56 3.2 Pollution Prevention (P2) 61 3.3 Ecotoxicology 62 3.4 Environmental
Assessment Analysis 64 3.5 What Can You Do to Make a Difference? 68
References 70 4 MATTER: THE HEART OF GREEN CHEMISTRY 73 4.1 Matter:
Definition, Classification, and the Periodic Table 73 4.1.1 Aluminum (Al)
75 4.1.2 Mercury (Hg) 76 4.1.3 Lead (Pb) 77 4.2 Atomic Structure 77 4.3
Three States of Matter 79 4.4 Molecular and Ionic Compounds 81 4.4.1
Molecular Compounds 82 4.4.2 Ionic Compounds 94 4.5 Chemical Reactions 100
4.6 Mixtures, Acids, and Bases 102 References 107 5 CHEMICAL REACTIONS 109
5.1 Definition of Chemical Reactions and Balancing of Chemical Equations
109 5.2 Chemical Reactions and Quantities of Reactants and Products 112 5.3
Patterns of Chemical Reactions 115 5.3.1 Combination, Synthesis, or
Addition Reactions 115 5.3.2 Decomposition Reactions 117 5.3.3 Elimination
Reactions 117 5.3.4 Displacement Reactions 118 5.3.5 Exchange or
Substitution Reactions 124 5.4 Effectiveness and Efficiency of Chemical
Reactions: Yield Versus Atom Economy 135 Reference 138 6 KINETICS,
CATALYSIS, AND REACTION ENGINEERING 139 6.1 Basic Concept of Rate 139 6.1.1
Definition of Reaction Rate 139 6.1.2 Parallel Reactions 142 6.1.3
Consecutive Reactions 146 6.1.4 Chemical Equilibrium 150 6.1.5 Effect of
Concentration on Reaction Rate 153 6.1.6 Effect of Temperature on Reaction
Rate 159 6.2 Role of Industrial and Biological Catalysts 162 6.2.1
Definition of Catalysts 162 6.2.2 Catalytic Kinetics 166 6.2.3 Types of
Catalysts and Impact on Green Chemistry 170 6.2.4 Biocatalysis 175 6.3
Reaction Engineering 181 6.3.1 Batch Reactor 181 6.3.2 Continuous Stirred
Tank Reactor 184 6.3.3 Plug Flow Reactor (PFR) 188 6.3.4 Multiphase Reactor
Design 191 6.4 Summary 194 References 194 7 THERMODYNAMICS, SEPARATIONS,
AND EQUILIBRIUM 197 7.1 Ideal Gases 197 7.2 The First Law of Thermodynamics
201 7.2.1 Closed System 203 7.2.2 Open System 204 7.3 Ideal Gas
Calculations 205 7.4 Entropy and the Second Law of Thermodynamics 210 7.5
Real Gas Properties 214 7.6 The Phase Diagram 217 7.7 Equilibrium 221 7.7.1
The Flash Calculation 227 7.8 Solubility of a Gas in a Liquid 229 7.9
Solubility of a Solid in a Liquid 230 7.10 Summary 233 References 233 8
RENEWABLE MATERIALS 235 8.1 Introduction 235 8.2 Renewable Feedstocks 236
8.2.1 Role of Biomass and Components 236 8.2.2 Production of Chemicals from
Renewable Resources 242 8.3 Applications of Renewable Materials 251 8.3.1
The Case of Biodegradable Plastics 251 8.3.2 The Case of Compostable
Chemicals 254 8.3.3 Production of Ethanol from Biomass 254 8.3.4 The Case
of Flex-Fuel Vehicles 256 8.3.5 Production of Biodiesel 258 8.4 Conclusion
261 References 261 9 CURRENT AND FUTURE STATE OF ENERGY PRODUCTION AND
CONSUMPTION 263 9.1 Introduction 263 9.2 Basic Thermodynamic Functions and
Applications 267 9.3 Other Chemical Processes for Energy Transfer 272 9.3.1
Microwave-Assisted Reactions 272 9.3.2 Sonochemistry 273 9.3.3
Electrochemistry 273 9.3.4 Photochemistry and Photovoltaic Cells 274 9.4
Renewable Sources of Energy in the 21st Century and Beyond 275 9.4.1 Solar
Energy 275 9.4.2 Wind Power 279 9.4.3 Geothermal Solution 281 9.4.4
Hydropower 283 9.4.5 The Case of Hydrogen Technology 284 9.4.6 Barriers to
Development 285 9.5 Concluding Thoughts About Sources of Energy and their
Future 285 References 286 10 THE ECONOMICS OF GREEN AND SUSTAINABLE
CHEMISTRY By David E. Meyer and Michael A. Gonzalez 287 10.1 Introduction
287 10.2 Chemical Manufacturing and Economic Theory 289 10.2.1 Plant
(Microscale) Scale Economics 290 10.2.2 Corporate Economics 290 10.2.3
Macroeconomics 292 10.3 Economic Impact of Green Chemistry 293 10.4
Business Strategies Regarding Application of Green Chemistry 306 10.5
Incorporation of Green Chemistry in Process Design for Sustainability 310
10.6 Case Studies Demonstrating the Economic Benefits of Green Chemistry
and Design 317 10.7 Summary 321 References 322 11 GREEN CHEMISTRY AND
TOXICOLOGY By Dale E. Johnson and Grace L. Anderson 325 11.1 Introduction
325 11.2 Fundamental Principles of Toxicology 326 11.2.1 Basic Concepts 326
11.2.2 Toxicokinetics 330 11.2.3 Cellular Toxicity 333 11.3 Identifying
Chemicals of Concern 335 11.3.1 Mode of Action Approaches 336 11.3.2
Adverse Outcome Pathways 337 11.3.3 Threshold of Toxicological Concern 338
11.3.4 Chemistry-Linked-to-Toxicity: Structural Alerts and Mechanistic
Domains 338 11.4 Toxicology Data 339 11.4.1 Authoritative Sources of
Information 339 11.4.2 Data Gaps: The Challenge and the Opportunity Arising
from New Technologies 340 11.5 Computational Toxicology and Green Chemistry
341 11.5.1 Tools for Predictions and Modeling 341 11.5.2 Interoperability
of Models for Decision Making and the Case for Metadata 346 11.6
Applications of Toxicology into Green Chemistry Initiatives 346 11.6.1
REACH 346 11.6.2 State of California Green Chemistry Initiatives 348 11.7
Future Perspectives 349 References 350 Index 355
1 1.1.1 Fermentation: An Ancient Chemical Process 2 1.1.2 The Advent of
Modern Chemistry 2 1.1.3 Chemistry in the 20th Century: The Growth of
Modern Processes 2 1.1.4 Risks of Chemicals in the Environment 6 1.1.5
Regulations: Controlling Chemical Processes 11 1.2 Twenty-first Century
Chemistry, aka Green Chemistry 13 1.2.1 Green chemistry and Pollution
Prevention 13 1.2.2 Sustainability 14 1.3 Layout of the Book 18 References
19 2 PRINCIPLES OF GREEN CHEMISTRY AND GREEN ENGINEERING 21 2.1
Introduction 21 2.2 Green Chemistry 23 2.2.1 Definition 23 2.2.2 Principles
of Green Chemistry and Examples 24 2.2.3 Presidential Green Chemistry
Challenge Awards 31 2.3 Green Engineering 34 2.3.1 Definition 34 2.3.2
Principles of Green Engineering 35 2.4 Sustainability 38 References 41 3
CHEMISTRY AS AN UNDERLYING FORCE IN ECOSYSTEM INTERACTIONS 43 3.1 Nature
and the Environment 44 3.1.1 Air and the Atmosphere (Outdoor and Indoor
Pollution) 44 3.1.2 Water (Water Pollutants, Issues Associated with
Nonpotable Drinking Water) 52 3.1.3 Chemistry of the Land 53 3.1.4 Energy
56 3.2 Pollution Prevention (P2) 61 3.3 Ecotoxicology 62 3.4 Environmental
Assessment Analysis 64 3.5 What Can You Do to Make a Difference? 68
References 70 4 MATTER: THE HEART OF GREEN CHEMISTRY 73 4.1 Matter:
Definition, Classification, and the Periodic Table 73 4.1.1 Aluminum (Al)
75 4.1.2 Mercury (Hg) 76 4.1.3 Lead (Pb) 77 4.2 Atomic Structure 77 4.3
Three States of Matter 79 4.4 Molecular and Ionic Compounds 81 4.4.1
Molecular Compounds 82 4.4.2 Ionic Compounds 94 4.5 Chemical Reactions 100
4.6 Mixtures, Acids, and Bases 102 References 107 5 CHEMICAL REACTIONS 109
5.1 Definition of Chemical Reactions and Balancing of Chemical Equations
109 5.2 Chemical Reactions and Quantities of Reactants and Products 112 5.3
Patterns of Chemical Reactions 115 5.3.1 Combination, Synthesis, or
Addition Reactions 115 5.3.2 Decomposition Reactions 117 5.3.3 Elimination
Reactions 117 5.3.4 Displacement Reactions 118 5.3.5 Exchange or
Substitution Reactions 124 5.4 Effectiveness and Efficiency of Chemical
Reactions: Yield Versus Atom Economy 135 Reference 138 6 KINETICS,
CATALYSIS, AND REACTION ENGINEERING 139 6.1 Basic Concept of Rate 139 6.1.1
Definition of Reaction Rate 139 6.1.2 Parallel Reactions 142 6.1.3
Consecutive Reactions 146 6.1.4 Chemical Equilibrium 150 6.1.5 Effect of
Concentration on Reaction Rate 153 6.1.6 Effect of Temperature on Reaction
Rate 159 6.2 Role of Industrial and Biological Catalysts 162 6.2.1
Definition of Catalysts 162 6.2.2 Catalytic Kinetics 166 6.2.3 Types of
Catalysts and Impact on Green Chemistry 170 6.2.4 Biocatalysis 175 6.3
Reaction Engineering 181 6.3.1 Batch Reactor 181 6.3.2 Continuous Stirred
Tank Reactor 184 6.3.3 Plug Flow Reactor (PFR) 188 6.3.4 Multiphase Reactor
Design 191 6.4 Summary 194 References 194 7 THERMODYNAMICS, SEPARATIONS,
AND EQUILIBRIUM 197 7.1 Ideal Gases 197 7.2 The First Law of Thermodynamics
201 7.2.1 Closed System 203 7.2.2 Open System 204 7.3 Ideal Gas
Calculations 205 7.4 Entropy and the Second Law of Thermodynamics 210 7.5
Real Gas Properties 214 7.6 The Phase Diagram 217 7.7 Equilibrium 221 7.7.1
The Flash Calculation 227 7.8 Solubility of a Gas in a Liquid 229 7.9
Solubility of a Solid in a Liquid 230 7.10 Summary 233 References 233 8
RENEWABLE MATERIALS 235 8.1 Introduction 235 8.2 Renewable Feedstocks 236
8.2.1 Role of Biomass and Components 236 8.2.2 Production of Chemicals from
Renewable Resources 242 8.3 Applications of Renewable Materials 251 8.3.1
The Case of Biodegradable Plastics 251 8.3.2 The Case of Compostable
Chemicals 254 8.3.3 Production of Ethanol from Biomass 254 8.3.4 The Case
of Flex-Fuel Vehicles 256 8.3.5 Production of Biodiesel 258 8.4 Conclusion
261 References 261 9 CURRENT AND FUTURE STATE OF ENERGY PRODUCTION AND
CONSUMPTION 263 9.1 Introduction 263 9.2 Basic Thermodynamic Functions and
Applications 267 9.3 Other Chemical Processes for Energy Transfer 272 9.3.1
Microwave-Assisted Reactions 272 9.3.2 Sonochemistry 273 9.3.3
Electrochemistry 273 9.3.4 Photochemistry and Photovoltaic Cells 274 9.4
Renewable Sources of Energy in the 21st Century and Beyond 275 9.4.1 Solar
Energy 275 9.4.2 Wind Power 279 9.4.3 Geothermal Solution 281 9.4.4
Hydropower 283 9.4.5 The Case of Hydrogen Technology 284 9.4.6 Barriers to
Development 285 9.5 Concluding Thoughts About Sources of Energy and their
Future 285 References 286 10 THE ECONOMICS OF GREEN AND SUSTAINABLE
CHEMISTRY By David E. Meyer and Michael A. Gonzalez 287 10.1 Introduction
287 10.2 Chemical Manufacturing and Economic Theory 289 10.2.1 Plant
(Microscale) Scale Economics 290 10.2.2 Corporate Economics 290 10.2.3
Macroeconomics 292 10.3 Economic Impact of Green Chemistry 293 10.4
Business Strategies Regarding Application of Green Chemistry 306 10.5
Incorporation of Green Chemistry in Process Design for Sustainability 310
10.6 Case Studies Demonstrating the Economic Benefits of Green Chemistry
and Design 317 10.7 Summary 321 References 322 11 GREEN CHEMISTRY AND
TOXICOLOGY By Dale E. Johnson and Grace L. Anderson 325 11.1 Introduction
325 11.2 Fundamental Principles of Toxicology 326 11.2.1 Basic Concepts 326
11.2.2 Toxicokinetics 330 11.2.3 Cellular Toxicity 333 11.3 Identifying
Chemicals of Concern 335 11.3.1 Mode of Action Approaches 336 11.3.2
Adverse Outcome Pathways 337 11.3.3 Threshold of Toxicological Concern 338
11.3.4 Chemistry-Linked-to-Toxicity: Structural Alerts and Mechanistic
Domains 338 11.4 Toxicology Data 339 11.4.1 Authoritative Sources of
Information 339 11.4.2 Data Gaps: The Challenge and the Opportunity Arising
from New Technologies 340 11.5 Computational Toxicology and Green Chemistry
341 11.5.1 Tools for Predictions and Modeling 341 11.5.2 Interoperability
of Models for Decision Making and the Case for Metadata 346 11.6
Applications of Toxicology into Green Chemistry Initiatives 346 11.6.1
REACH 346 11.6.2 State of California Green Chemistry Initiatives 348 11.7
Future Perspectives 349 References 350 Index 355
Preface Chapter 1: Understanding the Issues 1 A brief history of chemistry 2 Twenty-first century chemistry, aka Green Chemistry 3 The layout of the book Chapter 2: Principles of Green Chemistry and Green Engineering 1 Introduction 2 Green Chemistry 3 Green Engineering 4 Sustainability Chapter 3: Chemistry as an Underlying Force in Ecosystem Interactions 1 Nature and the environment 2 Pollution Prevention 3 Ecotoxicology 4 Environmental assessment analysis 5 What can YOU do to make a difference? Chapter 4: Matter: The Heart of Green Chemistry 1 Matter: definition, classification, and the periodic table 2 The atomic structure 3 The three states of matter 4 Molecular and ionic compounds 5 Chemical reactions 6 Mixtures, acids, and bases Chapter 5: Chemical Reactions 1 Definition of chemical reactions and balancing of chemical equations 2 Chemical reactions and quantities of reactants and products 3 Patterns of chemical reactions 4 Effectiveness and efficiency of chemical reactions-Yield vs atom Chapter 6: Kinetics, Catalysis, and Reaction Engineering 1 Basic concept of rate 2 Role of industrial and biological catalysts 3 Reaction engineering 4 Summary Chapter 7: Thermodynamics, Separations and Equilibrium 1 Ideal gases 2 The first law of thermodynamics 3 Ideal gas calculations 4 Entropy and the second law of thermodynamics 5 Real gas properties 6 The phase diagram 7 Equilibrium 8 Solubility of a gas in a liquid 9 Solubility of a solid in a liquid 10 Summary Chapter 8: Renewable Materials 1 Introduction 2 Renewable feedstocks 3 Applications of renewable materials 4 Concluding thoughts Chapter 9: Current and Future State of Energy Production and Consumption 1 Introduction 2 Basic thermodynamic functions and applications 3 Other chemical processes for energy transfer 4 Renewable sources of energy in the 21st century and beyond 5 Concluding thoughts about sources of energy and their future Chapter 10: The Economics of Green and Sustainable Chemistry (Michael Gonzales) 1 Introduction 2 Chemical manufacturing and economic theory 3 The economic impact of green chemistry 4 Business strategies regarding application of green chemistry 5 Incorporation of green chemistry in process design for sustainability 6 Case studies demonstrating the economic benefits of green chemistry and design 7 Summary Chapter 11: Green Chemistry and Toxicology (Dale E Johnson and Grace L Anderson) 1 Introduction 2 Fundamental principles of toxicology 3 Identifying chemicals of concern 4 Toxicology data 5 Computational Toxicology and green chemistry 6 Applications of toxicology into green chemistry initiatives 7 Future perspectives
Preface xiii 1 UNDERSTANDING THE ISSUES 1 1.1 A Brief History of Chemistry
1 1.1.1 Fermentation: An Ancient Chemical Process 2 1.1.2 The Advent of
Modern Chemistry 2 1.1.3 Chemistry in the 20th Century: The Growth of
Modern Processes 2 1.1.4 Risks of Chemicals in the Environment 6 1.1.5
Regulations: Controlling Chemical Processes 11 1.2 Twenty-first Century
Chemistry, aka Green Chemistry 13 1.2.1 Green chemistry and Pollution
Prevention 13 1.2.2 Sustainability 14 1.3 Layout of the Book 18 References
19 2 PRINCIPLES OF GREEN CHEMISTRY AND GREEN ENGINEERING 21 2.1
Introduction 21 2.2 Green Chemistry 23 2.2.1 Definition 23 2.2.2 Principles
of Green Chemistry and Examples 24 2.2.3 Presidential Green Chemistry
Challenge Awards 31 2.3 Green Engineering 34 2.3.1 Definition 34 2.3.2
Principles of Green Engineering 35 2.4 Sustainability 38 References 41 3
CHEMISTRY AS AN UNDERLYING FORCE IN ECOSYSTEM INTERACTIONS 43 3.1 Nature
and the Environment 44 3.1.1 Air and the Atmosphere (Outdoor and Indoor
Pollution) 44 3.1.2 Water (Water Pollutants, Issues Associated with
Nonpotable Drinking Water) 52 3.1.3 Chemistry of the Land 53 3.1.4 Energy
56 3.2 Pollution Prevention (P2) 61 3.3 Ecotoxicology 62 3.4 Environmental
Assessment Analysis 64 3.5 What Can You Do to Make a Difference? 68
References 70 4 MATTER: THE HEART OF GREEN CHEMISTRY 73 4.1 Matter:
Definition, Classification, and the Periodic Table 73 4.1.1 Aluminum (Al)
75 4.1.2 Mercury (Hg) 76 4.1.3 Lead (Pb) 77 4.2 Atomic Structure 77 4.3
Three States of Matter 79 4.4 Molecular and Ionic Compounds 81 4.4.1
Molecular Compounds 82 4.4.2 Ionic Compounds 94 4.5 Chemical Reactions 100
4.6 Mixtures, Acids, and Bases 102 References 107 5 CHEMICAL REACTIONS 109
5.1 Definition of Chemical Reactions and Balancing of Chemical Equations
109 5.2 Chemical Reactions and Quantities of Reactants and Products 112 5.3
Patterns of Chemical Reactions 115 5.3.1 Combination, Synthesis, or
Addition Reactions 115 5.3.2 Decomposition Reactions 117 5.3.3 Elimination
Reactions 117 5.3.4 Displacement Reactions 118 5.3.5 Exchange or
Substitution Reactions 124 5.4 Effectiveness and Efficiency of Chemical
Reactions: Yield Versus Atom Economy 135 Reference 138 6 KINETICS,
CATALYSIS, AND REACTION ENGINEERING 139 6.1 Basic Concept of Rate 139 6.1.1
Definition of Reaction Rate 139 6.1.2 Parallel Reactions 142 6.1.3
Consecutive Reactions 146 6.1.4 Chemical Equilibrium 150 6.1.5 Effect of
Concentration on Reaction Rate 153 6.1.6 Effect of Temperature on Reaction
Rate 159 6.2 Role of Industrial and Biological Catalysts 162 6.2.1
Definition of Catalysts 162 6.2.2 Catalytic Kinetics 166 6.2.3 Types of
Catalysts and Impact on Green Chemistry 170 6.2.4 Biocatalysis 175 6.3
Reaction Engineering 181 6.3.1 Batch Reactor 181 6.3.2 Continuous Stirred
Tank Reactor 184 6.3.3 Plug Flow Reactor (PFR) 188 6.3.4 Multiphase Reactor
Design 191 6.4 Summary 194 References 194 7 THERMODYNAMICS, SEPARATIONS,
AND EQUILIBRIUM 197 7.1 Ideal Gases 197 7.2 The First Law of Thermodynamics
201 7.2.1 Closed System 203 7.2.2 Open System 204 7.3 Ideal Gas
Calculations 205 7.4 Entropy and the Second Law of Thermodynamics 210 7.5
Real Gas Properties 214 7.6 The Phase Diagram 217 7.7 Equilibrium 221 7.7.1
The Flash Calculation 227 7.8 Solubility of a Gas in a Liquid 229 7.9
Solubility of a Solid in a Liquid 230 7.10 Summary 233 References 233 8
RENEWABLE MATERIALS 235 8.1 Introduction 235 8.2 Renewable Feedstocks 236
8.2.1 Role of Biomass and Components 236 8.2.2 Production of Chemicals from
Renewable Resources 242 8.3 Applications of Renewable Materials 251 8.3.1
The Case of Biodegradable Plastics 251 8.3.2 The Case of Compostable
Chemicals 254 8.3.3 Production of Ethanol from Biomass 254 8.3.4 The Case
of Flex-Fuel Vehicles 256 8.3.5 Production of Biodiesel 258 8.4 Conclusion
261 References 261 9 CURRENT AND FUTURE STATE OF ENERGY PRODUCTION AND
CONSUMPTION 263 9.1 Introduction 263 9.2 Basic Thermodynamic Functions and
Applications 267 9.3 Other Chemical Processes for Energy Transfer 272 9.3.1
Microwave-Assisted Reactions 272 9.3.2 Sonochemistry 273 9.3.3
Electrochemistry 273 9.3.4 Photochemistry and Photovoltaic Cells 274 9.4
Renewable Sources of Energy in the 21st Century and Beyond 275 9.4.1 Solar
Energy 275 9.4.2 Wind Power 279 9.4.3 Geothermal Solution 281 9.4.4
Hydropower 283 9.4.5 The Case of Hydrogen Technology 284 9.4.6 Barriers to
Development 285 9.5 Concluding Thoughts About Sources of Energy and their
Future 285 References 286 10 THE ECONOMICS OF GREEN AND SUSTAINABLE
CHEMISTRY By David E. Meyer and Michael A. Gonzalez 287 10.1 Introduction
287 10.2 Chemical Manufacturing and Economic Theory 289 10.2.1 Plant
(Microscale) Scale Economics 290 10.2.2 Corporate Economics 290 10.2.3
Macroeconomics 292 10.3 Economic Impact of Green Chemistry 293 10.4
Business Strategies Regarding Application of Green Chemistry 306 10.5
Incorporation of Green Chemistry in Process Design for Sustainability 310
10.6 Case Studies Demonstrating the Economic Benefits of Green Chemistry
and Design 317 10.7 Summary 321 References 322 11 GREEN CHEMISTRY AND
TOXICOLOGY By Dale E. Johnson and Grace L. Anderson 325 11.1 Introduction
325 11.2 Fundamental Principles of Toxicology 326 11.2.1 Basic Concepts 326
11.2.2 Toxicokinetics 330 11.2.3 Cellular Toxicity 333 11.3 Identifying
Chemicals of Concern 335 11.3.1 Mode of Action Approaches 336 11.3.2
Adverse Outcome Pathways 337 11.3.3 Threshold of Toxicological Concern 338
11.3.4 Chemistry-Linked-to-Toxicity: Structural Alerts and Mechanistic
Domains 338 11.4 Toxicology Data 339 11.4.1 Authoritative Sources of
Information 339 11.4.2 Data Gaps: The Challenge and the Opportunity Arising
from New Technologies 340 11.5 Computational Toxicology and Green Chemistry
341 11.5.1 Tools for Predictions and Modeling 341 11.5.2 Interoperability
of Models for Decision Making and the Case for Metadata 346 11.6
Applications of Toxicology into Green Chemistry Initiatives 346 11.6.1
REACH 346 11.6.2 State of California Green Chemistry Initiatives 348 11.7
Future Perspectives 349 References 350 Index 355
1 1.1.1 Fermentation: An Ancient Chemical Process 2 1.1.2 The Advent of
Modern Chemistry 2 1.1.3 Chemistry in the 20th Century: The Growth of
Modern Processes 2 1.1.4 Risks of Chemicals in the Environment 6 1.1.5
Regulations: Controlling Chemical Processes 11 1.2 Twenty-first Century
Chemistry, aka Green Chemistry 13 1.2.1 Green chemistry and Pollution
Prevention 13 1.2.2 Sustainability 14 1.3 Layout of the Book 18 References
19 2 PRINCIPLES OF GREEN CHEMISTRY AND GREEN ENGINEERING 21 2.1
Introduction 21 2.2 Green Chemistry 23 2.2.1 Definition 23 2.2.2 Principles
of Green Chemistry and Examples 24 2.2.3 Presidential Green Chemistry
Challenge Awards 31 2.3 Green Engineering 34 2.3.1 Definition 34 2.3.2
Principles of Green Engineering 35 2.4 Sustainability 38 References 41 3
CHEMISTRY AS AN UNDERLYING FORCE IN ECOSYSTEM INTERACTIONS 43 3.1 Nature
and the Environment 44 3.1.1 Air and the Atmosphere (Outdoor and Indoor
Pollution) 44 3.1.2 Water (Water Pollutants, Issues Associated with
Nonpotable Drinking Water) 52 3.1.3 Chemistry of the Land 53 3.1.4 Energy
56 3.2 Pollution Prevention (P2) 61 3.3 Ecotoxicology 62 3.4 Environmental
Assessment Analysis 64 3.5 What Can You Do to Make a Difference? 68
References 70 4 MATTER: THE HEART OF GREEN CHEMISTRY 73 4.1 Matter:
Definition, Classification, and the Periodic Table 73 4.1.1 Aluminum (Al)
75 4.1.2 Mercury (Hg) 76 4.1.3 Lead (Pb) 77 4.2 Atomic Structure 77 4.3
Three States of Matter 79 4.4 Molecular and Ionic Compounds 81 4.4.1
Molecular Compounds 82 4.4.2 Ionic Compounds 94 4.5 Chemical Reactions 100
4.6 Mixtures, Acids, and Bases 102 References 107 5 CHEMICAL REACTIONS 109
5.1 Definition of Chemical Reactions and Balancing of Chemical Equations
109 5.2 Chemical Reactions and Quantities of Reactants and Products 112 5.3
Patterns of Chemical Reactions 115 5.3.1 Combination, Synthesis, or
Addition Reactions 115 5.3.2 Decomposition Reactions 117 5.3.3 Elimination
Reactions 117 5.3.4 Displacement Reactions 118 5.3.5 Exchange or
Substitution Reactions 124 5.4 Effectiveness and Efficiency of Chemical
Reactions: Yield Versus Atom Economy 135 Reference 138 6 KINETICS,
CATALYSIS, AND REACTION ENGINEERING 139 6.1 Basic Concept of Rate 139 6.1.1
Definition of Reaction Rate 139 6.1.2 Parallel Reactions 142 6.1.3
Consecutive Reactions 146 6.1.4 Chemical Equilibrium 150 6.1.5 Effect of
Concentration on Reaction Rate 153 6.1.6 Effect of Temperature on Reaction
Rate 159 6.2 Role of Industrial and Biological Catalysts 162 6.2.1
Definition of Catalysts 162 6.2.2 Catalytic Kinetics 166 6.2.3 Types of
Catalysts and Impact on Green Chemistry 170 6.2.4 Biocatalysis 175 6.3
Reaction Engineering 181 6.3.1 Batch Reactor 181 6.3.2 Continuous Stirred
Tank Reactor 184 6.3.3 Plug Flow Reactor (PFR) 188 6.3.4 Multiphase Reactor
Design 191 6.4 Summary 194 References 194 7 THERMODYNAMICS, SEPARATIONS,
AND EQUILIBRIUM 197 7.1 Ideal Gases 197 7.2 The First Law of Thermodynamics
201 7.2.1 Closed System 203 7.2.2 Open System 204 7.3 Ideal Gas
Calculations 205 7.4 Entropy and the Second Law of Thermodynamics 210 7.5
Real Gas Properties 214 7.6 The Phase Diagram 217 7.7 Equilibrium 221 7.7.1
The Flash Calculation 227 7.8 Solubility of a Gas in a Liquid 229 7.9
Solubility of a Solid in a Liquid 230 7.10 Summary 233 References 233 8
RENEWABLE MATERIALS 235 8.1 Introduction 235 8.2 Renewable Feedstocks 236
8.2.1 Role of Biomass and Components 236 8.2.2 Production of Chemicals from
Renewable Resources 242 8.3 Applications of Renewable Materials 251 8.3.1
The Case of Biodegradable Plastics 251 8.3.2 The Case of Compostable
Chemicals 254 8.3.3 Production of Ethanol from Biomass 254 8.3.4 The Case
of Flex-Fuel Vehicles 256 8.3.5 Production of Biodiesel 258 8.4 Conclusion
261 References 261 9 CURRENT AND FUTURE STATE OF ENERGY PRODUCTION AND
CONSUMPTION 263 9.1 Introduction 263 9.2 Basic Thermodynamic Functions and
Applications 267 9.3 Other Chemical Processes for Energy Transfer 272 9.3.1
Microwave-Assisted Reactions 272 9.3.2 Sonochemistry 273 9.3.3
Electrochemistry 273 9.3.4 Photochemistry and Photovoltaic Cells 274 9.4
Renewable Sources of Energy in the 21st Century and Beyond 275 9.4.1 Solar
Energy 275 9.4.2 Wind Power 279 9.4.3 Geothermal Solution 281 9.4.4
Hydropower 283 9.4.5 The Case of Hydrogen Technology 284 9.4.6 Barriers to
Development 285 9.5 Concluding Thoughts About Sources of Energy and their
Future 285 References 286 10 THE ECONOMICS OF GREEN AND SUSTAINABLE
CHEMISTRY By David E. Meyer and Michael A. Gonzalez 287 10.1 Introduction
287 10.2 Chemical Manufacturing and Economic Theory 289 10.2.1 Plant
(Microscale) Scale Economics 290 10.2.2 Corporate Economics 290 10.2.3
Macroeconomics 292 10.3 Economic Impact of Green Chemistry 293 10.4
Business Strategies Regarding Application of Green Chemistry 306 10.5
Incorporation of Green Chemistry in Process Design for Sustainability 310
10.6 Case Studies Demonstrating the Economic Benefits of Green Chemistry
and Design 317 10.7 Summary 321 References 322 11 GREEN CHEMISTRY AND
TOXICOLOGY By Dale E. Johnson and Grace L. Anderson 325 11.1 Introduction
325 11.2 Fundamental Principles of Toxicology 326 11.2.1 Basic Concepts 326
11.2.2 Toxicokinetics 330 11.2.3 Cellular Toxicity 333 11.3 Identifying
Chemicals of Concern 335 11.3.1 Mode of Action Approaches 336 11.3.2
Adverse Outcome Pathways 337 11.3.3 Threshold of Toxicological Concern 338
11.3.4 Chemistry-Linked-to-Toxicity: Structural Alerts and Mechanistic
Domains 338 11.4 Toxicology Data 339 11.4.1 Authoritative Sources of
Information 339 11.4.2 Data Gaps: The Challenge and the Opportunity Arising
from New Technologies 340 11.5 Computational Toxicology and Green Chemistry
341 11.5.1 Tools for Predictions and Modeling 341 11.5.2 Interoperability
of Models for Decision Making and the Case for Metadata 346 11.6
Applications of Toxicology into Green Chemistry Initiatives 346 11.6.1
REACH 346 11.6.2 State of California Green Chemistry Initiatives 348 11.7
Future Perspectives 349 References 350 Index 355