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Author: Adrienne Claire Lukaski Publisher: ProQuest ISBN: 9780549924647 Category : Chemical reactions Languages : en Pages :
Book Description
Direct oxidation processes, such as ethylene epoxidation to ethylene oxide, have been researched extensively due to the uniqueness of this process and to the commercial significance of the epoxide product. Despite the importance of epoxide production, the mechanistic details of olefin epoxidation remained obscure until recently and the majority of significant advances in Ag catalyst development occurred primarily through empirical methods. Recent surface science studies of ethylene oxide on Ag(111) have identified an oxametallacycle as the active intermediate in ethylene epoxidation; expansion of the epoxide ring to incorporate surface silver atoms forms the oxametallacycle species. Oxametallacycles have been isolated by ring-opening ethylene oxide on Ag(111) and Ag(110), 1-epoxy-3-butene on Ag(111) and Ag(110), styrene oxide on Ag(111) and Ag(110) and isoprene oxide and propylene oxide on Ag(110). Surface science techniques and Density Functional Theory (DFT) were used in this study to investigate the interactions of styrene oxide and isoprene oxide with the Ag(110) surface, as well as the interactions of ethylene oxide and propylene oxide with the clean and O-covered Ag(110) surfaces. TPD experiments demonstrate that the styrene oxide ring opens at the substituted carbon, and DFT calculations indicate that the phenyl ring of the resulting oxametallacycle is oriented nearly parallel to the Ag(110) surface. Interaction of the phenyl group with the silver surface stabilizes this intermediate relative to that derived from the mono-olefin epoxide, ethylene oxide. During TPD, the oxametallacycle undergoes ring closure to reform styrene oxide and isomerization to phenylacetaldehyde at 505 K on Ag(110). Styrene oxide-derived oxametallacycles exhibit similar ring-closure behavior on the Ag(111) surface. Isoprene oxide also forms a strongly bound oxametallacycle intermediate on the Ag(110) surface. The oxametallacycle undergoes ring-closure to reform isoprene oxide in two peaks at 320 and 460 K when synthesized by epoxide adsorption at low temperatures. Epoxide doses at higher surface temperatures (ca. 300 K) lead to isomerization of the oxametallacycle and desorption of the aldehyde isomer, 2-methyl-2-butenal, in a single peak at 460 K. This work represents the first demonstration of a surface oxametallacycle species derived from an allylic epoxide. Similar to oxametallacycles derived from the non-allylic epoxides, isoprene oxide ring opens at the carbon bound to the unsaturated vinyl and methyl substituent groups to form a linear oxametallacycle on the Ag(110) surface. The structure of the isoprene oxide-derived oxametallacycle resembles that formed from ring-opening its non-allylic counterpart, 1-epoxy-3-butene, on Ag(110), according to DFT calculations. Following adsorption at 250 K on both clean and O-covered Ag(110), ethylene oxide ring-opens to form a stable oxametallacycle. On the clean Ag(110) surface, the oxametallacycle reacts to reform the parent epoxide at 280 K during TPD, while the aldehyde isomer, acetaldehyde, is observed at higher oxametallacycle coverages. In the presence of coadsorbed oxygen atoms, a portion of the oxametallacycles dissociate to release ethylene. However, of those that react to form oxygen-containing products, the fraction forming ethylene oxide is similar to that on the clean surface. The acetaldehyde product of oxametallacycle reactions combusts via formation of acetate species; the acetates react to form CO 2 at temperatures as low as 360 K on the O-covered surface. No evidence was observed for other combustion channels. This work provides experimental evidence for the connection of oxametallacycles to combustion via acetaldehyde formation, as well as to ring-closure to form ethylene oxide. Adsorption of propylene oxide at 120 K with subsequent flash of the surface to 230 K prior to TPD leads to the formation of a stable oxametallacycle on both the clean and O-covered Ag(110) surfaces; the oxametallacycle then undergoes ring-closure to reform propylene oxide at 250 K during TPD. The selectivity to propylene oxide decreases at higher oxametallacycle coverages where acetone and allyl alcohol are formed; carbon dioxide is also formed near 250, 350, and 450 K from reactions of the oxametallacycle and its products on the O-covered surface. At higher oxametallacycle coverages, additional higher temperature desorptions are observed at 300 and 400 K; the product distributions in these peaks are the same as that in the 250 K peak. Similar to reactions of ethylene oxide on the O-covered Ag(110) surface, the same fraction of oxametallacycle species reacts to form propylene oxide in the presence of co-adsorbed oxygen as that on the clean surface, although the coverage of oxametallacycles is 10-20% higher on the O-covered surface. The principal effects of co-adsorbed oxygen are to increase the capacity of the surface and to open an additional combustion pathway to CO 2 . The oxametallacycle undergoes combustion through a propionaldehyde species. This work represents the first time that an oxametallacycle has been linked to propylene oxide production.
Author: Adrienne Claire Lukaski Publisher: ProQuest ISBN: 9780549924647 Category : Chemical reactions Languages : en Pages :
Book Description
Direct oxidation processes, such as ethylene epoxidation to ethylene oxide, have been researched extensively due to the uniqueness of this process and to the commercial significance of the epoxide product. Despite the importance of epoxide production, the mechanistic details of olefin epoxidation remained obscure until recently and the majority of significant advances in Ag catalyst development occurred primarily through empirical methods. Recent surface science studies of ethylene oxide on Ag(111) have identified an oxametallacycle as the active intermediate in ethylene epoxidation; expansion of the epoxide ring to incorporate surface silver atoms forms the oxametallacycle species. Oxametallacycles have been isolated by ring-opening ethylene oxide on Ag(111) and Ag(110), 1-epoxy-3-butene on Ag(111) and Ag(110), styrene oxide on Ag(111) and Ag(110) and isoprene oxide and propylene oxide on Ag(110). Surface science techniques and Density Functional Theory (DFT) were used in this study to investigate the interactions of styrene oxide and isoprene oxide with the Ag(110) surface, as well as the interactions of ethylene oxide and propylene oxide with the clean and O-covered Ag(110) surfaces. TPD experiments demonstrate that the styrene oxide ring opens at the substituted carbon, and DFT calculations indicate that the phenyl ring of the resulting oxametallacycle is oriented nearly parallel to the Ag(110) surface. Interaction of the phenyl group with the silver surface stabilizes this intermediate relative to that derived from the mono-olefin epoxide, ethylene oxide. During TPD, the oxametallacycle undergoes ring closure to reform styrene oxide and isomerization to phenylacetaldehyde at 505 K on Ag(110). Styrene oxide-derived oxametallacycles exhibit similar ring-closure behavior on the Ag(111) surface. Isoprene oxide also forms a strongly bound oxametallacycle intermediate on the Ag(110) surface. The oxametallacycle undergoes ring-closure to reform isoprene oxide in two peaks at 320 and 460 K when synthesized by epoxide adsorption at low temperatures. Epoxide doses at higher surface temperatures (ca. 300 K) lead to isomerization of the oxametallacycle and desorption of the aldehyde isomer, 2-methyl-2-butenal, in a single peak at 460 K. This work represents the first demonstration of a surface oxametallacycle species derived from an allylic epoxide. Similar to oxametallacycles derived from the non-allylic epoxides, isoprene oxide ring opens at the carbon bound to the unsaturated vinyl and methyl substituent groups to form a linear oxametallacycle on the Ag(110) surface. The structure of the isoprene oxide-derived oxametallacycle resembles that formed from ring-opening its non-allylic counterpart, 1-epoxy-3-butene, on Ag(110), according to DFT calculations. Following adsorption at 250 K on both clean and O-covered Ag(110), ethylene oxide ring-opens to form a stable oxametallacycle. On the clean Ag(110) surface, the oxametallacycle reacts to reform the parent epoxide at 280 K during TPD, while the aldehyde isomer, acetaldehyde, is observed at higher oxametallacycle coverages. In the presence of coadsorbed oxygen atoms, a portion of the oxametallacycles dissociate to release ethylene. However, of those that react to form oxygen-containing products, the fraction forming ethylene oxide is similar to that on the clean surface. The acetaldehyde product of oxametallacycle reactions combusts via formation of acetate species; the acetates react to form CO 2 at temperatures as low as 360 K on the O-covered surface. No evidence was observed for other combustion channels. This work provides experimental evidence for the connection of oxametallacycles to combustion via acetaldehyde formation, as well as to ring-closure to form ethylene oxide. Adsorption of propylene oxide at 120 K with subsequent flash of the surface to 230 K prior to TPD leads to the formation of a stable oxametallacycle on both the clean and O-covered Ag(110) surfaces; the oxametallacycle then undergoes ring-closure to reform propylene oxide at 250 K during TPD. The selectivity to propylene oxide decreases at higher oxametallacycle coverages where acetone and allyl alcohol are formed; carbon dioxide is also formed near 250, 350, and 450 K from reactions of the oxametallacycle and its products on the O-covered surface. At higher oxametallacycle coverages, additional higher temperature desorptions are observed at 300 and 400 K; the product distributions in these peaks are the same as that in the 250 K peak. Similar to reactions of ethylene oxide on the O-covered Ag(110) surface, the same fraction of oxametallacycle species reacts to form propylene oxide in the presence of co-adsorbed oxygen as that on the clean surface, although the coverage of oxametallacycles is 10-20% higher on the O-covered surface. The principal effects of co-adsorbed oxygen are to increase the capacity of the surface and to open an additional combustion pathway to CO 2 . The oxametallacycle undergoes combustion through a propionaldehyde species. This work represents the first time that an oxametallacycle has been linked to propylene oxide production.
Author: Gabriele Centi Publisher: Springer Science & Business Media ISBN: 1461541751 Category : Science Languages : en Pages : 519
Book Description
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: S. Ted Oyama Publisher: Elsevier ISBN: 0080558011 Category : Technology & Engineering Languages : en Pages : 524
Book Description
The catalytic epoxidation of olefins plays an important role in the industrial production of several commodity compounds, as well as in the synthesis of many intermediates, fine chemicals, and pharmaceuticals. The scale of production ranges from millions of tons per year to a few grams per year. The diversity of catalysts is large and encompasses all the known categories of catalyst type: homogeneous, heterogeneous, and biological. This book summarizes the current status in these fields concentrating on rates, kinetics, and reaction mechanisms, but also covers broad topics including modeling, computational simulation, process concepts, spectroscopy and new catalyst development. The similarities and distinctions between the different reaction systems are compared, and the latest advances are described. Comprehensive listing of epoxide products Broad comparison of turnover frequencies of homogeneous, hetergeneous, main-group, biomimetic and biological catalysts Analysis of the general strengths and weaknesses of varied catalytic systems Detailed description of the mechanisms of reaction for classical and emerging catalysts
Author: Loutfy H. Madkour Publisher: Springer ISBN: 3030216217 Category : Technology & Engineering Languages : en Pages : 783
Book Description
This book presents synthesis techniques for the preparation of low-dimensional nanomaterials including 0D (quantum dots), 1D (nanowires, nanotubes) and 2D (thin films, few layers), as well as their potential applications in nanoelectronic systems. It focuses on the size effects involved in the transition from bulk materials to nanomaterials; the electronic properties of nanoscale devices; and different classes of nanomaterials from microelectronics to nanoelectronics, to molecular electronics. Furthermore, it demonstrates the structural stability, physical, chemical, magnetic, optical, electrical, thermal, electronic and mechanical properties of the nanomaterials. Subsequent chapters address their characterization, fabrication techniques from lab-scale to mass production, and functionality. In turn, the book considers the environmental impact of nanotechnology and novel applications in the mechanical industries, energy harvesting, clean energy, manufacturing materials, electronics, transistors, health and medical therapy. In closing, it addresses the combination of biological systems with nanoelectronics and highlights examples of nanoelectronic–cell interfaces and other advanced medical applications. The book answers the following questions: • What is different at the nanoscale? • What is new about nanoscience? • What are nanomaterials (NMs)? • What are the fundamental issues in nanomaterials? • Where are nanomaterials found? • What nanomaterials exist in nature? • What is the importance of NMs in our lives? • Why so much interest in nanomaterials? • What is at nanoscale in nanomaterials? • What is graphene? • Are pure low-dimensional systems interesting and worth pursuing? • Are nanotechnology products currently available? • What are sensors? • How can Artificial Intelligence (AI) and nanotechnology work together? • What are the recent advances in nanoelectronic materials? • What are the latest applications of NMs?
Author: Murray D. Dailey Publisher: Univ of California Press ISBN: 9780520075788 Category : Nature Languages : en Pages : 952
Book Description
Here is a benchmark study of one significant stretch of the Pacific Ocean, the Southern California Bight. Extending from Point Conception to the Mexican border and out to the 200-mile limit, these waters have never before been investigated in such detail, from so many points of view, by such an eminent group of scientists. The twenty-five expert contributors summarize everything known about the physical, chemical, geological, and biological characteristics of the area in individual chapters; the volume concludes with a synthesis of the information presented. In addition, chapters are devoted to the influence of humans on the marine environment and to the various laws and governmental agencies concerned with protecting it. Because Southern California is so heavily populated and because the ocean is a major recreational area for its people, the information in this unique volume will be invaluable for the region's planners and decisionmakers as well as for all those who study the globe's marine resources and ecology.
Author: American Chemical Society, Committee on Professional Training Staff Publisher: ISBN: 9780841214187 Category : Science Languages : en Pages : 1390
Author: Christopher S. Foote Publisher: Springer Science & Business Media ISBN: 9400708742 Category : Science Languages : en Pages : 355
Book Description
Taking an interdisciplinary approach, this book and its counterpart, Active Oxygen in Biochemistry, explore the active research area of the chemistry and biochemistry of oxygen. Complementary but independent, the two volumes integrate subject areas including medicine, biology, chemistry, engineering, and environmental studies.
Author: F J J G Janssen Publisher: World Scientific ISBN: 1783262265 Category : Science Languages : en Pages : 385
Book Description
This book brings together highlights of a theme which is growing in interest: the creation of a sustainable society using catalysis as the main tool. Catalysts play key roles in the production of clean fuels, the conversion of waste and green raw materials into energy, clean combustion engines including control of NOx and soot production and reduction of greenhouse gases, production of clean water and of polymers, as well as reduction from polymers to monomers. Catalysts are also of prime importance in the developing H2 and syngas production technology, aimed at producing clean fuels for the coming decades. And catalysts can be recycled.
Author: R.M. Lambert Publisher: Springer Science & Business Media ISBN: 9401589119 Category : Science Languages : en Pages : 534
Book Description
Heterogeneous catalysis provides the backbone of the world's chemical and oil industries. The innate complexity of practical catalytic systems suggests that useful progress should be achievable by investigating key aspects of catalysis by experimental studies on idealised model systems. Thin films and supported clusters are two promising types of model system that can be used for this purpose, since they mimic important aspects of the properties of practical dispersed catalysts. Similarly, appropriate theoretical studies of chemisorption and surface reaction clusters or extended slab systems can provide valuable information on the factors that underlie bonding and catalytic activity. This volume describes such experimental and theoretical approaches to the surface chemistry and catalytic behaviour of metals, metal oxides and metal/metal oxide systems. An introduction to the principles and main themes of heterogeneous catalysis is followed by detailed accounts of the application of modern experimental and theoretical techniques to fundamental problems. The application of advanced experimental methods is complemented by a full description of theoretical procedures, including Hartree-Fock, density functional and similar techniques. The relative merits of the various approaches are considered and directions for future progress are indicated.
Author: Adrienne Claire Lukaski
Author: Adrienne Claire Lukaski
Author: Gabriele Centi
Author: 
Author: S. Ted Oyama
Author: Loutfy H. Madkour
Author: Murray D. Dailey
Author: American Chemical Society, Committee on Professional Training Staff
Author: Christopher S. Foote
Author: F J J G Janssen
Author: R.M. Lambert