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09333nam a22003017a 4500 |
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CITU |
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20240628081907.0 |
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210809b ||||| |||| 00| 0 eng d |
| 020 ## - INTERNATIONAL STANDARD BOOK NUMBER |
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| International Standard Book Number |
0195169255 |
| 020 ## - INTERNATIONAL STANDARD BOOK NUMBER |
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| International Standard Book Number |
9780195169256 |
| 041 ## - LANGUAGE CODE |
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| Language code of text/sound track or separate title |
eng |
| 082 ## - DEWEY DECIMAL CLASSIFICATION NUMBER |
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| Edition number |
660.2832 |
| 100 1# - MAIN ENTRY--PERSONAL NAME |
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| Preferred name for the person |
Schmidt, Lanny D., |
| Dates associated with a name |
1938- |
| Relator term |
author |
| 245 ## - TITLE STATEMENT |
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| Title |
The engineering of chemical reactions / |
| Statement of responsibility, etc |
Lanny D. Schmidt. |
| 250 ## - EDITION STATEMENT |
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| Edition statement |
Second Edition |
| 264 #1 - PUBLICATION, DISTRIBUTION, ETC. (IMPRINT) |
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| Place of publication, distribution, etc |
New York: |
| Name of publisher, distributor, etc |
Oxford University Press, |
| Date of publication, distribution, etc |
c2005. |
| 300 ## - PHYSICAL DESCRIPTION |
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| Extent |
xx, 618 pages : |
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illustrations ; |
| Dimensions |
25 cm. |
| 336 ## - CONTENT TYPE |
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| Content type term |
text |
| Content type code |
txt |
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rdacontent |
| 337 ## - MEDIA TYPE |
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unmediated |
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n |
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rdamedia |
| 338 ## - CARRIER TYPE |
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volume |
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nc |
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rdacarrier |
| 440 ## - SERIES STATEMENT/ADDED ENTRY--TITLE |
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| Title |
Topics in chemical engineering (Oxford University Press) |
| 505 ## - CONTENTS |
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| Formatted contents note |
Each Chapter ends with Problems. Most chapters end with References.<br/>Preface to the Second Edition<br/>Preface to the First Edition<br/>PART I: FUNDAMENTALS <br/>1. Introduction <br/>1.1. Chemical Reactors<br/>1.2. Chemical Reaction Engineering<br/>1.3. What Do We Need To Know?<br/>1.4. Industrial Processes<br/>1.5. Modeling<br/>1.6. Sources<br/>2. Reaction Rates, The Batch Reactor, and The Real World <br/>2.1. Chemical Reactions<br/>2.2. Multiple Reactions<br/>2.3. Reaction Rates<br/>2.4. Approximate Reactions<br/>2.5. Rate Coefficients<br/>2.6. Elementary Reactions<br/>2.7. Stoichiometry<br/>2.8. Reaction Rates Near Equilibrium<br/>2.9. Reactor Mass Balances<br/>2.10. The Batch Reactor<br/>2.11. Variable Density<br/>2.12. Chemical Reactors<br/>2.13. Thermodynamics and Reactors<br/>2.14. Adiabatic Reactor Temperature<br/>2.15. Chemical Equilibrium<br/>2.16. Petroleum Refining<br/>2.17. Polyester from Refinery Products and Natural Gas<br/>2.18. "What Should I Do When I Don't Have Reaction Rates?"<br/>2.19. Reaction-Rate Data<br/>2.20. Summary<br/>3. Single Reactions in Continuous Isothermal Reactors <br/>3.1. Continuous Reactors<br/>3.2. The Continuous Stirred Tank Reactor<br/>3.3. Conversion in a Constant-Density CSTR<br/>3.4. The Plug-Flow Tubular Reactor<br/>3.5. Conversion in a Constant-Density PFTR<br/>3.6. Comparison Between Batch, CSTR, and PFTR<br/>3.7. The 1/r Plot<br/>3.8. Semibatch Reactors<br/>3.9. Variable-Density Reactors<br/>3.10. Space Velocity and Space Time<br/>3.11. Chemical Reactors in a Series<br/>3.12. Autocatalytic Reactions<br/>3.13. Reversible Reactions<br/>3.14. Transients in Continuous Reactions<br/>3.15. Some Important Single-Reaction Processes: Alkane Activation<br/>3.16. Synthesis Gas Reactions<br/>3.17. Staged Reactors<br/>3.18. The Major Chemical Companies<br/>3.19. Reactor Design for a Single Reaction<br/>3.20. Notation<br/>4. Multiple Reactions in Continuous Reactors <br/>4.1. Some Important Industrial Chemical Processes<br/>4.2. The Petrochemical Industry<br/>4.3. Olefins<br/>4.4. Mass Balances<br/>4.5. Conversion, Selectivity, and Yield<br/>4.6. Complex Reaction Networks<br/>4.7. Series Reactions<br/>4.8. Parallel Reactions<br/>4.9. Multiple Reactions with Variable Density<br/>4.10. Real Reaction Systems and Modeling<br/>4.11. Approximate Rate Expressions for Multiple-Reaction Systems<br/>4.12. Simplified Reactions<br/>4.13. Reaction Mechanisms<br/>4.14. Collision Theory of Bimolecular Reactions<br/>4.15. Activated Complex Theory<br/>4.16. Designing Reactors for Multiple Reactions<br/>5. Nonisothermal Reactors <br/>5.1. Heat Generation and Removal<br/>5.2. Energy Balance in a CSTR<br/>5.3. Energy Balance in a PFTR<br/>5.4. Equations to be Solved<br/>5.5. Heat Removal or Addition to Maintain a Reactor Isothermal<br/>5.6. Adiabatic Reactors<br/>5.7. Trajectories and Phase-Plane Plots<br/>5.8. Trajectories of Wall-Cooled Reactors<br/>5.9. Exothermic Versus Endothermic Reactions<br/>5.10. Other Tubular Reactor Configurations<br/>5.11. Temperature Profile in a Packed Bed<br/>6. Multiple Steady States and Transients <br/>6.1. Heat Generation and Removal in a CSTR<br/>6.2. Adiabatic CSTR<br/>6.3. Stability of Steady States in a CSTR<br/>6.4. Observation of Multiple Steady States<br/>6.5. Transients in the CSTR with Multiple Steady States<br/>6.6. Other Reactions in a CSTR<br/>6.7. Variable Coolant Temperature in a CSTR<br/>6.8. Designing Reactors for Energy Management<br/>7. Catalytic Reactors and Mass Transfer <br/>7.1. Catalytic Reactions<br/>7.2. Catalytic Reactors<br/>7.3. Surface and Enzyme Reaction Rates<br/>7.4. Porous Catalysts<br/>7.5. Transport and Reactions<br/>7.6. Mass Transfer Coefficients<br/>7.7. External Mass Transfer<br/>7.8. Pore Diffusion<br/>7.9. Temperature Dependence of Catalytic Reaction Rates<br/>7.10. The Automotive Catalytic Converter<br/>7.11. The Catalytic Wall Reactor<br/>7.12. Langmuir-Hinshelwood Kinetics<br/>7.13. Summary of Surface Reaction Kinetics<br/>7.14. Designing Catalytic Reactors<br/>7.15. Electrochemical Reactors<br/>7.16. Real Catalytic Reactors<br/>7.17. Bioreactors<br/>7.18. The Human Reactor<br/>PART II: APPLICATIONS <br/>8. Nonideal Chemical Reactions <br/>8.1. The "Complete" Equations<br/>8.2. Reactor Mass and Energy Balances<br/>8.3. Residence Time Distribution<br/>8.4. Laminar Flow Tubular Reactors<br/>8.5. Dispersion in Tubular Reactors<br/>8.6. Recycle Reactors<br/>8.7. CSTRs in Series<br/>8.8. Diagnosing Reactors<br/>8.9. Summary<br/>9. Reactions of Solids <br/>9.1. Reactions Involving Solids<br/>9.2. Chemical Vapor Deposition and Reactive Etching<br/>9.3. Solids Reactors<br/>9.4. Reaction Rates of Solids<br/>9.5. Films, Spheres, and Cylinders<br/>9.6. Macroscopic and Microscopic Solids<br/>9.7. Dissolving and Growing Films<br/>9.8. Dissolving and Growing Spheres<br/>9.9. Diffusion Through Solid Films<br/>9.10. Transformation of Spheres<br/>9.11. Mass Balances in Solid and Continuous Phases<br/>9.12. Electrical Analogy<br/>9.13. Summary<br/>10. Chain Reactions, Combustion Reactors, and Safety <br/>10.1. Chain Reactions<br/>10.2. Characteristics of Chain Reactions<br/>10.3. Autooxidation and Lab Safety<br/>10.4. Chemical Synthesis and Autooxidation<br/>10.5. Combustion<br/>10.6. Hydrogen Oxodation<br/>10.7. Chain Branching Reactions<br/>10.8. Alkane Oxidation<br/>10.9. Thermal Ignition<br/>10.10. Thermal and Chemical Autocatalysis<br/>10.11. Premixed Flames<br/>10.12. Diffusion Flames<br/>10.13. Energy Generation<br/>10.14. Combustion of Liquids and Solids<br/>10.15. Solid and Liquid Explosives<br/>10.16. Explosions and Detonations<br/>10.17. Reactor Safety<br/>10.18. Summary<br/>11. Polymerization Reactions and Reactors <br/>11.1. Ideal Addition Polymerization<br/>11.2. Polyolefins<br/>11.3. Free-Radical Polymerization<br/>11.4. Catalytic Polymerization<br/>11.5. Condensation Polymerization<br/>11.6. Fischer Tropsch Polymerization<br/>11.7. Polymerization Reactors<br/>11.8. Forming Polymers<br/>11.9. Integrated Polymer Processing<br/>11.10. Crystallization<br/>12. Biological Reaction Engineering <br/>12.1. Introduction<br/>12.2. Biological Molecules<br/>12.3. Cells<br/>12.4. Origins and Changes in Living Systems<br/>12.5. Bioenergy and Metabolic Pathways<br/>12.6. Measurements in Biological Systems<br/>12.7. Rates and Kinetics of Biological Processes<br/>12.8. Biochemical Engineering<br/>12.9. Chemically Synthesized Biological Molecules<br/>12.10. Economics of Bioprocesses<br/>12.11. Biological Reactors<br/>12.12. Summary<br/>13. Environmental Reaction Engineering <br/>13.1. Only Chemical Engineers Can Solve Environmental Problems<br/>13.2. Green Chemistry<br/>13.3. Renewable Chemical Resources<br/>13.4. Regulations<br/>13.5. Accidents<br/>13.6. Waste Treatment<br/>13.7. Modeling the Environment<br/>13.8. Ecological Modeling<br/>13.9. Summary<br/>14. Multiphase Reactors <br/>14.1. Types of Multiphase Reactors<br/>14.2. Mass Transfer Reactors<br/>14.3. Mass Balance Equations<br/>14.4. Interfacial Surface Area<br/>14.5. Mass Transfer Between Phases<br/>14.6. Multiphase Reactor Equations<br/>14.7. Equilibrium Between Phases<br/>14.8. Membrane Reactors<br/>14.9. Falling Film Reactor<br/>14.10. Bubble Column Reactors<br/>14.11. Falling Film Catalytic Wall Reactor<br/>14.12. Trickle Bed Reactor<br/>14.13. Multiphase Reactors with Catalysts<br/>14.14. Other Multiphase Reactors<br/>14.15. Analysis of Multiphase Reactors<br/>14.16. Reactor-Separation Integration<br/>14.17. Catalytic Distillation<br/>14.18. Chromatographic Reactors<br/>14.19. Iron Ore Refining<br/>14.20. The Petroleum Refinery<br/>14.21. Summary<br/>Appendix A: Integrating Differential Equations<br/>Appendix B: Notation<br/>Appendix C: Conversion Factors<br/>Index |
| 520 ## - SUMMARY, ETC. |
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| Summary, etc |
Thoroughly revised and updated in this second edition, The Engineering of Chemical Reactions focuses explicitly on developing the skills necessary to design a chemical reactor for any application, including chemical production, materials processing, and environmental modeling. This edition also features two new chapters on biological and environmental reaction engineering that provide an exciting introduction to these increasingly important areas of today's chemical engineering market. Streamlined to enhance the logical flow of the subject, The Engineering of Chemical Reactions, 2/e, is easy for instructors to navigate and students to follow. Using real reactions from chemical engineering, the first seven chapters cover such fundamentals as multiple reactions, energy management, and catalytic processes. The final five chapters explore more advanced topics including environmental, polymer, solids processing, biological, and combustion reactions. Practical, real-world examples throughout the text consider reactor and process choices in ways that encourage students to think creatively and build on previous knowledge. The Engineering of Chemical Reactions, 2/e, is ideal for upper-level undergraduate courses in chemical reactor engineering, chemical reactor design, and kinetics. |
| 650 #0 - SUBJECT ADDED ENTRY--TOPICAL TERM |
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| Topical term or geographic name as entry element |
Chemical reactors. |
| 856 ## - ELECTRONIC LOCATION AND ACCESS |
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| Materials specified |
http://www.loc.gov/catdir/enhancements/fy0617/2004043285-t.html |
| 942 ## - ADDED ENTRY ELEMENTS |
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| Source of classification or shelving scheme |
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| Item type |
BOOK |