did-you-know? rent-now

Amazon no longer offers textbook rentals. We do!

did-you-know? rent-now

Amazon no longer offers textbook rentals. We do!

We're the #1 textbook rental company. Let us show you why.

9780306462658

Selective Oxidation by Heterogeneous Catalysis

by ; ;
  • ISBN13:

    9780306462658

  • ISBN10:

    0306462656

  • Format: Hardcover
  • Copyright: 2000-11-01
  • Publisher: Plenum Pub Corp

Note: Supplemental materials are not guaranteed with Rental or Used book purchases.

Purchase Benefits

  • Free Shipping Icon Free Shipping On Orders Over $35!
    Your order must be $35 or more to qualify for free economy shipping. Bulk sales, PO's, Marketplace items, eBooks and apparel do not qualify for this offer.
  • eCampus.com Logo Get Rewarded for Ordering Your Textbooks! Enroll Now
  • Write a Review Icon Write a Review
List Price: $349.99 Save up to $279.45
  • Buy Used
    $262.49
    Add to Cart Free Shipping Icon Free Shipping

    USUALLY SHIPS IN 2-4 BUSINESS DAYS

Supplemental Materials

What is included with this book?

Summary

Selective Oxidation by Heterogeneous Catalysis covers one of the major areas of industrial petrochemical production, outlining open questions and new opportunities. It gives keys for the interpretation and analysis of data and design of new catalysts and reactions, and provides guidelines for future research. A distinctive feature of this book is the use of concept by example. Rather than reporting an overview of the literature results, the authors have selected some representative examples, the in-depth analysis of which makes it possible to clarify the fundamental, but new concepts necessary for a better understanding of the new opportunities in this field and the design of new catalysts or catalytic reactions. Attention is given not only to the catalyst itself, but also to the use of the catalyst inside the process, thus evidencing the relationship between catalyst design and engineering aspects of the process. This book provides suggestions for new innovative directions of research and indications on how to reconsider the field of selective oxidation from different perspectives, outlining that is not a mature field of research, but that new important breakthroughs can be derived from fundamental and applied research. Suggestions are offered on how to use less conventional approaches in terms of both catalyst design and analysis of the data.

Author Biography

Fabrizio Cavani is Professor in charge of Industrial Chemistry at the University of Bologna, Italy.

Table of Contents

Trends and Outlook in selective Oxidation: and Introduction
Introduction
1(4)
Technological and Industrial Developments
5(8)
New Raw Materials
5(3)
Conversion of Air-Based to Oxygen-Based Processes
8(2)
Fine-Tuning Existing Oxidation Processes
10(2)
Reducing the Number of Process Steps
12(1)
New Opportunities Derived from Basic Research
13(2)
The Ecological Issue as a Driving Force
15(4)
Reduction or Elimination of Corpoducts
15(1)
Synthesis of Propene Oxide
16(1)
Synthesis of Cyclohexanone Oxime
16(1)
Synthesis of Methyl Methacrylate
17(1)
Use of Alternative Catalysts
17(2)
Heterogeneous Versus Homogeneous Catalysis in Selective Oxidation
19(6)
References
22(3)
New Technological and Industrial Opportunities: Options
Use of Alternative Raw Materials
25(12)
Alkanes as Raw Materials for Selective Oxidation Reactions
25(1)
Advantages and Targets in Using and Alkane Feedstock
26(3)
Key Questions in Alkane Functionalization
29(1)
Processes of Industrial Interest Using an Alkane Feedstock
30(2)
New Oxidants
32(1)
Nitrous Oxide
33(2)
Ozone
35(1)
In Situ Generated Oxidants in the Liquid Phase
35(2)
New Reactor Technology Options
37(30)
Fixed-Bed Reactors
38(1)
The Problem of Hot Spots in Both the Axial and Radial Directions
38(1)
Heat and Mass Gradients
39(4)
Presence of Multiple Steady States and Runaway Phenomena
43(2)
Wide-Residence Time Distribution
45(1)
High Pressure Drop
45(1)
Technologies Designed to Overcome Drawbacks of Fixed-Bed Reactors
46(1)
Dual-Bed Reactors
46(1)
Distributed Inlet of One Reactant
46(1)
Periodic Flow Reversal
47(1)
Decoupling of the Exothermal Reaction into Two Steps
48(1)
Integration of Exothermal and Endothermal Processes
49(1)
Radial Flow Reactors
49(1)
Fluidized-Bed Reactors
49(4)
High-Gas-Velocity Systems: Circulating Fluidized-Bed Reactors
53(3)
Structured Catalysts and Reactors
56(4)
Monolith Reactors
60(3)
Membrane Reactors
63(2)
Electrochemical Cells as Reactors
65(2)
Air Versus Oxygen Processes
67(18)
Advantages in the Use of Oxygen Instead of Air in Industrial Oxidation Processes
67(2)
Synthesis of Ethene Epolxide
69(2)
Synthesis of 1,2-Dichloroethane (DCE)
71(2)
Use of Pure Oxygen in the Oxidation of Alkanes
73(1)
References
74(11)
New Technological and Industrial Opportunities: Examples
Introduction
85(2)
Examples of Opportunities for New Oxidation Processes
87(33)
Selective Oxidation for Fine Chemicals and Pharmaceuticals
87(1)
Oxidation with Hydrogen Peroxide and Organic Peroxide
87(4)
Oxidation with Molecular Oxygen and Noble Metal-Based Catalysts
91(4)
Bioinorganic-Type Oxidation
95(5)
New Catalytic Processes for Bulk Chemicals Using Hydrogen Peroxide
100(1)
Alkene Epoxidation Reactions
101(8)
Cyclothexanone Ammoximation
109(6)
Hydroxylation of Phenols
115(5)
Examples of New Catalytic Systems
120(12)
Metalloporphyrin Complexes
122(2)
Polyoxometallates
124(1)
Supported Metals
125(1)
Isomorphically Substituted Molecular Sieves
126(1)
Redox Pillared Clays
127(1)
Phase-Transfer Catalysts
128(1)
Guest Oxide Nanoparticles within Host Zeo-Type Materials
129(3)
Conclusions
132(9)
References
132(9)
Control of the Surface Reactivity of Solid Catalysts: Industrial Processes of Alkane Oxidation
Introduction
141(2)
Maleic Anhydride from n-Butane on Vanadium/Phosphorus Oxides
143(28)
Industrial Processes of Maleic Anhydride Synthesis from n-Butane
143(2)
Gas Phase Composition
145(1)
Reactor Technologies
146(2)
Catalyst Formulation
148(3)
V/P Oxide Catalysts Synthesis and Characteristics
151(1)
Role of the Precursor Phase
151(2)
Activation and Conditioning Procedure
153(3)
Role of the P/V Ratio and Catalyst Redox Properties
156(1)
Role of Promoters
157(1)
Structure of the V/P Oxide Phases
158(3)
Advanced Aspects toward Understanding the Catalytic Chemistry of V/P Oxides
161(1)
Role of Catalyst Microstructure and Topology
161(5)
In Situ Surface Restructuring of VPO Catalysts
166(2)
Catalyst Properties and Reactor/Process Configuration
168(2)
Microkinetics of the Surface Transformations on V/P Oxide Catalysts
170(1)
Alkane Versus Alkene Oxidation
170(1)
Propane Ammoxidation to Acrylonitrile on Vanadium/Antimony Oxides
171(32)
Background on the Direct Synthesis of Acrylonitrile from Propane
171(2)
Role of Nonstoichiometry and Rutile Structure in V/Sb Oxide Catalysts
173(2)
Comparison with Other Sb-Rich Rutilelike Mixed Oxide Catalysts
175(1)
Nature of the Phases Present
176(1)
Nonstoichiometry of Vanadium Antimonate and Catalytic Reactivity
177(5)
Nonstoichiometry of Vanadium Antimonate and Surface Characteristics
182(2)
Role of Microstructure
184(1)
Surface Reaction Network as a Tool for Understanding and Controlling Reactivity
185(1)
The Surface Reaction Network in Propane Ammoxidation over V/Sb Oxide Catalysts
186(1)
The Surface Reaction Network as A Tool For Understanding the Surface Reactivity
187(3)
Designing Better Catalysts
190(1)
Conclusions
191(1)
References
192(11)
Control of the Surface Reactivity of Solid Catalysts: New Alkane Oxidation Reactions
Introduction
203(1)
Oxidative Dehydrogenation of Alkanes
204(37)
Dehydrogenation versus Oxidative Dehydrogenation
204(3)
Constraints in Oxidative Dehydrogenation
207(7)
Class of Catalysts Active in Oxidative-Dehydrogenation
214(1)
Alkali and Alkaline Earth-Based Catalysts
215(5)
Catalysts Based on Transition Metal Oxides
220(6)
Catalysts and Reaction Mechanisms
226(4)
Role of the Nature of the Alkane
230(9)
Conclusions
239(2)
New Types of Oxidation of Light Alkanes
241(44)
Introduction
241(2)
Ethane Conversion
243(1)
Catalysts for Acetaldehyde and Acetic Acid Formation
243(3)
Alternative Approaches for Catalyst Design
246(3)
A New Route: Ethane Ammoxidation
249(4)
Propane Conversion
253(1)
Acrolein Synthesis
253(3)
Acrylic Acid Synthesis
256(3)
Isobutane Conversion to Methacrolein and Methacrylic Acid
259(7)
n-Pentane Conversion to Maleic and Phthalic Anhydrides
266(5)
Cyclohexane (Amm) oxidation
271(1)
References
272(13)
New Fields of Application For Solid Catalysts
Introduction
285(2)
Selective Oxidation in the Liquid Phase with Solid Micro-or Mesoporous Materials
287(13)
Framework Substitution
289(1)
Synthesis, Characteristics, and Reactivity of Titanium Silicalite
290(1)
Reactivity
290(1)
Synthesis
291(2)
Characterization
293(1)
Nature of Active Species
294(4)
Encapsulated Metal Complexes
298(1)
Grafting or Tethering of Metal Complexes
298(1)
New ``Hydrophobic'' Catalytic Materials for Liquid Phase Epoxidation of Alkanes
299(1)
Heteropoly Compounds as Molecular-Type Catalysts
300(10)
Introduction
300(1)
Redox Properties of HPCs
301(2)
Liquid Phase Oxidation
303(1)
Oxidation with Molecular Oxygen
303(2)
Oxidation with Hydrogen Peroxide, with Organic Peroxides or Other Monoxygen Donors
305(4)
Gas Phase Oxidation: General Aspects
309(1)
Solid Wacker-Type Catalysts
310(15)
Palladium Supported on Monolayer-Type Redox Oxides
311(2)
Solid Palladium-Heteropoly Compounds
313(1)
Heterogenization of Wacker Catalysts in Microporous Materials
314(1)
References
315(10)
New Concepts and New Strategies in Selective Oxidation
Introduction
325(1)
Selective Oxidation at Near Room Temperature Using Molecular Oxygen
326(14)
Electrochemical Activation of Molecular Oxygen
327(1)
Benzene to Phenol
328(2)
Alkane Oxidation
330(1)
π-Allyl and Wacker Oxidation of Alkenes
331(3)
Activation of Molecular Oxygen by Spontaneous Charge Transfer from a Hydrocarbon
334(2)
Oxidation of Alkenes
336(1)
Oxidation of Alkylaromatics
337(1)
Oxidation of Alkanes
337(2)
Singlet Molecular Oxygen
339(1)
New Approaches to Generate Active Oxygen Species
340(10)
In Situ Generation of Monoxygen Donors
340(1)
Methods of in Situ Generation of H2O2
341(3)
Oxidation Reactions with in Situ Generated Hydrogen Peroxide
344(1)
Generation of Active Oxygen Species by Ozone
345(1)
Use of Nitrous Oxide as a Selective Oxidant
345(1)
Reactivity of α-Oxygen
346(2)
Use of Waste Nitrous Oxide Streams: Adipic Acid Production
348(2)
Novel Reaction Mediums
350(6)
Oxidations Reaction at Thin Supported Liquid Films
350(1)
Heterogeneous Wacker-Type Catalysts
350(2)
Ethene Acetoxylation to Vinyl Acetate
352(2)
Other Cases
354(1)
Oxidation Reaction under Supercritical Conditions
355(1)
Conclusions
356(7)
References
357(6)
New Aspects of the Mechanisms of Selective Oxidation and Structure/Activity Relationships
Introduction
363(6)
Outline and Scope of this Chapter
363(1)
The Established Approach to Modeling Reaction Mechanisms at Oxide Surfaces
364(5)
Active Sites or ``Living Active Surface''?
369(17)
The Mechanism of Propene (Amm) oxidation
369(1)
Analysis of the Model of the Mechanism of Propene (Amm) oxidation
370(2)
Toward a Model of ``Living Active Surface'' Rather than Localized Catalysis at Active Sites
372(3)
The Question of Stepwise Reaction Mechanisms
375(1)
The Geometrical Approach to Oxidation Catalysis at Oxide Surfaces
376(3)
The Question of Reaction at a Single ``Ensemble'' Site
379(2)
The Role of Catalyst Reduction and Dynamics of Reaction
381(3)
General Conclusions on the Modeling Approach to Selective Oxidation Catalysis
384(2)
Surface Oxygen Species and Their Role in Selective Oxidation
386(27)
Nature of the Interaction between Molecular Oxygen and Oxide Surfaces and Types of Oxygen Adspecies
388(1)
Neutral Dioxygen Species
389(1)
Charged Dioxygen Species
390(2)
Monoxygen Species
392(3)
Reactivity of Adsorbed Oxygen Species
395(3)
New Aspects of the Reactivity of Surface Oxygen Species
398(15)
Modification of the Surface Reactivity by Chemisorbed Species
413(12)
The Role of Alkenes in the Self-Modification of the Surface Reactivity
414(4)
The Role of the Nature of Intermediate Products
418(2)
Chemisorption and Change in the Surface Pathways of Transformation
420(2)
Direct Role of Chemisorbed (Spectator) Species in the Reaction Mechanism
422(3)
Role of Acido-Base Properties in Catalytic Oxidation
425(14)
Basic Concepts on the Acido-Base Characteristics of Metal Oxides
426(3)
Influence of Acido-Base Characteristics on the Activation of Hydrocarbons
429(2)
Competitive Surface Reactions and Acido-Base Properties
431(7)
Role of Acido-Base Properties on the Adsorption/Desorption of Reactants and Products
438(1)
Reactive Intermediates in Heterogeneous Oxidative Catalysis
439(17)
Analysis of the Reactive Intermediates by IR Spectroscopy
439(2)
Chemistry of Oxidation of Methanol
441(5)
Oxidation of Linear C4 Hydrocarbons
446(3)
Oxidation of Alkylaromatics
449(5)
The Case of Ammonia
454(2)
Presence of Competitive Pathways of Conversion and Factors Governing Their Relative Rates
456(13)
Propane Ammoxidation on (VO)2P2O7
457(2)
Toluene Ammoxidation (VO)2P2O7 and V/TiO2 Catalysts
459(2)
Propane Ammoxidation on V/Sb Oxides
461(5)
o-Xylene Ammoxidation on V/TiO2 Catalysts
466(2)
Oxidation of n-Pentane on (VO)2P2O7
468(1)
Dynamics of Catalytic Oxidation Processes
469(9)
Relevant Evidence from Surface Science Studies
470(5)
Dynamics of Oxide Phase Transformation in the Active Form of the Catalysts
475(2)
Dynamics of Surface Species and Their Effect on Catalyst Surface Properties
477(1)
Conclusions
478(19)
References
480(17)
General Conclusions
497(4)
Index 501

Supplemental Materials

What is included with this book?

The New copy of this book will include any supplemental materials advertised. Please check the title of the book to determine if it should include any access cards, study guides, lab manuals, CDs, etc.

The Used, Rental and eBook copies of this book are not guaranteed to include any supplemental materials. Typically, only the book itself is included. This is true even if the title states it includes any access cards, study guides, lab manuals, CDs, etc.

Rewards Program