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This book invites you on a tour through the most relevant topics of solid-state chemistry. It provides an up-to-date overview about fascinating structures of inorganic matter and new research developments. The reader will also gain crucial insights into many aspects of material science, from ceramics to superconductors. One chapter is specifically dedicated to the most rapidly evolving field of material science: metal-organic frameworks (MOFs). The book contains a chapter which is often neglected in others due to its complexity, the intermetallic phases. A concise but very didactic introduction to crystallographic specifications ensures that the reader will gain a deeper understanding of the crystal structures presented in the book. The book places special emphasis on the graphical illustrations which were specifically designed to promote real insights into the structural features. Instead of having to decipher hard to distinguish graphics the reader has an eye-opening experience. A further added value is that many references to the original research publications are given which enables easy follow-up for more detailed study.
Crystallography. --- Metal-Organic Framework. --- Semiconductor. --- Solid-State Chemistry.
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Thin films are important in many of the technologies used every day, impacting major markets for energy, medicine, and coatings. Scientists and engineers have been producing thin films on a wide range of surfaces for many decades but now have begun to explore giving these films new and controlled structures at the nanometer scale. These efforts are part of the new horizons opened by the field of nanoscience and impart novel structures and properties to these thin films. This book covers some of the methods for making these nanostructured thin films and their applications in areas impacting on health and energy usage.
Technology: general issues --- electrospinning --- poly(ethylene oxide) --- nanofiber diameter --- molecular weight --- concentration --- plasmonics --- localized surface plasmon resonance (LSPR) --- biosensing --- thin film --- gold nanostructures --- lithography --- nanohole array --- nanofabrication --- diphosphate-diarsenate --- crystal structure --- electrical properties --- transport pathways simulation --- metal–organic framework --- fabrication --- patterning --- tri-sodium citrate --- ZnO rod arrays --- response surface methodology --- expanded graphite --- flexible --- polydimethylsiloxane --- stretchable --- thin films --- n/a --- metal-organic framework
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Thin films are important in many of the technologies used every day, impacting major markets for energy, medicine, and coatings. Scientists and engineers have been producing thin films on a wide range of surfaces for many decades but now have begun to explore giving these films new and controlled structures at the nanometer scale. These efforts are part of the new horizons opened by the field of nanoscience and impart novel structures and properties to these thin films. This book covers some of the methods for making these nanostructured thin films and their applications in areas impacting on health and energy usage.
Technology: general issues --- electrospinning --- poly(ethylene oxide) --- nanofiber diameter --- molecular weight --- concentration --- plasmonics --- localized surface plasmon resonance (LSPR) --- biosensing --- thin film --- gold nanostructures --- lithography --- nanohole array --- nanofabrication --- diphosphate-diarsenate --- crystal structure --- electrical properties --- transport pathways simulation --- metal–organic framework --- fabrication --- patterning --- tri-sodium citrate --- ZnO rod arrays --- response surface methodology --- expanded graphite --- flexible --- polydimethylsiloxane --- stretchable --- thin films --- n/a --- metal-organic framework
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Thin films are important in many of the technologies used every day, impacting major markets for energy, medicine, and coatings. Scientists and engineers have been producing thin films on a wide range of surfaces for many decades but now have begun to explore giving these films new and controlled structures at the nanometer scale. These efforts are part of the new horizons opened by the field of nanoscience and impart novel structures and properties to these thin films. This book covers some of the methods for making these nanostructured thin films and their applications in areas impacting on health and energy usage.
electrospinning --- poly(ethylene oxide) --- nanofiber diameter --- molecular weight --- concentration --- plasmonics --- localized surface plasmon resonance (LSPR) --- biosensing --- thin film --- gold nanostructures --- lithography --- nanohole array --- nanofabrication --- diphosphate-diarsenate --- crystal structure --- electrical properties --- transport pathways simulation --- metal–organic framework --- fabrication --- patterning --- tri-sodium citrate --- ZnO rod arrays --- response surface methodology --- expanded graphite --- flexible --- polydimethylsiloxane --- stretchable --- thin films --- n/a --- metal-organic framework
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Metal organic frameworks (MOFs) are a class of porous materials with a modular structure. This allows for very wide structural diversity and the possibility of synthesizing materials with tailored properties for advanced applications. Thus, MOF materials are the subject of intense research, with strong relevance to both science and technology. MOFs are formed by the assembly of two components: cluster or metal ion nodes, which are also called secondary building units (SBUs), and organic linkers between the SBUs, usually giving rise to crystalline structures with an open framework and significant porous texture development. The main aim of this Special Issue of Catalysts (ISSN 2073-4344) is to present the most relevant and recent insights in the field of the synthesis and characterization of MOFs and MOF-based materials for advanced applications, including adsorption, gas storage/capture, drug delivery, catalysis, photocatalysis, and/or chemical sensing.
Technology: general issues --- History of engineering & technology --- Materials science --- Metal–organic framework --- Lewis acid --- fructose --- 5-hydroxymethyl furfural --- biomass --- Metal-organic frameworks (MOFs) --- photocatalysis --- carbon dioxide reduction --- renewable energy --- heterogeneous catalysis --- metal organic framework --- surface modification --- Zinc glutarate --- CO2 fixation --- polycarbonate --- Mn-MOF-74 --- modification --- water resistance --- NH3-SCR performance --- environmental pollution --- filter --- gas sorption --- sensor --- hydrogen storage --- electrospinning --- one-pot hydrothermal --- immobilizing recombinant --- His-hCA II --- Ni-BTC nanorods --- metal–organic frameworks --- polyoxometalates --- hybrid materials --- synthesis --- catalysis --- heterogeneous catalyst --- aerobic oxidation --- cyclohexene --- metal organic frameworks --- NH2-MIL-125(Ti) --- water stability --- purification --- layered coordination polymer --- oxidative desulfurization --- denitrogenation extraction --- hydrogen peroxide --- lanthanides --- MOF --- catalyst --- microreactor --- kinetic studies --- metal organic frame works --- CO2 adsorption --- pre combustion --- gas membrane separation --- metal halide perovskites --- metal-organic framework --- fuel cell --- oxygen reduction reaction (ORR) --- metal organic frameworks (MOFs) --- hydrothermal synthesis --- coordination polymers --- crystal structures --- metal-organic frameworks --- carboxylate ligands --- olefin paraffin separations --- propyne --- propylene --- adsorption isotherms --- dynamic breakthrough --- n/a --- Metal-organic framework
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Metal organic frameworks (MOFs) are a class of porous materials with a modular structure. This allows for very wide structural diversity and the possibility of synthesizing materials with tailored properties for advanced applications. Thus, MOF materials are the subject of intense research, with strong relevance to both science and technology. MOFs are formed by the assembly of two components: cluster or metal ion nodes, which are also called secondary building units (SBUs), and organic linkers between the SBUs, usually giving rise to crystalline structures with an open framework and significant porous texture development. The main aim of this Special Issue of Catalysts (ISSN 2073-4344) is to present the most relevant and recent insights in the field of the synthesis and characterization of MOFs and MOF-based materials for advanced applications, including adsorption, gas storage/capture, drug delivery, catalysis, photocatalysis, and/or chemical sensing.
Technology: general issues --- History of engineering & technology --- Materials science --- Metal–organic framework --- Lewis acid --- fructose --- 5-hydroxymethyl furfural --- biomass --- Metal-organic frameworks (MOFs) --- photocatalysis --- carbon dioxide reduction --- renewable energy --- heterogeneous catalysis --- metal organic framework --- surface modification --- Zinc glutarate --- CO2 fixation --- polycarbonate --- Mn-MOF-74 --- modification --- water resistance --- NH3-SCR performance --- environmental pollution --- filter --- gas sorption --- sensor --- hydrogen storage --- electrospinning --- one-pot hydrothermal --- immobilizing recombinant --- His-hCA II --- Ni-BTC nanorods --- metal–organic frameworks --- polyoxometalates --- hybrid materials --- synthesis --- catalysis --- heterogeneous catalyst --- aerobic oxidation --- cyclohexene --- metal organic frameworks --- NH2-MIL-125(Ti) --- water stability --- purification --- layered coordination polymer --- oxidative desulfurization --- denitrogenation extraction --- hydrogen peroxide --- lanthanides --- MOF --- catalyst --- microreactor --- kinetic studies --- metal organic frame works --- CO2 adsorption --- pre combustion --- gas membrane separation --- metal halide perovskites --- metal-organic framework --- fuel cell --- oxygen reduction reaction (ORR) --- metal organic frameworks (MOFs) --- hydrothermal synthesis --- coordination polymers --- crystal structures --- metal-organic frameworks --- carboxylate ligands --- olefin paraffin separations --- propyne --- propylene --- adsorption isotherms --- dynamic breakthrough --- n/a --- Metal-organic framework
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Metal organic frameworks (MOFs) are a class of porous materials with a modular structure. This allows for very wide structural diversity and the possibility of synthesizing materials with tailored properties for advanced applications. Thus, MOF materials are the subject of intense research, with strong relevance to both science and technology. MOFs are formed by the assembly of two components: cluster or metal ion nodes, which are also called secondary building units (SBUs), and organic linkers between the SBUs, usually giving rise to crystalline structures with an open framework and significant porous texture development. The main aim of this Special Issue of Catalysts (ISSN 2073-4344) is to present the most relevant and recent insights in the field of the synthesis and characterization of MOFs and MOF-based materials for advanced applications, including adsorption, gas storage/capture, drug delivery, catalysis, photocatalysis, and/or chemical sensing.
Metal–organic framework --- Lewis acid --- fructose --- 5-hydroxymethyl furfural --- biomass --- Metal-organic frameworks (MOFs) --- photocatalysis --- carbon dioxide reduction --- renewable energy --- heterogeneous catalysis --- metal organic framework --- surface modification --- Zinc glutarate --- CO2 fixation --- polycarbonate --- Mn-MOF-74 --- modification --- water resistance --- NH3-SCR performance --- environmental pollution --- filter --- gas sorption --- sensor --- hydrogen storage --- electrospinning --- one-pot hydrothermal --- immobilizing recombinant --- His-hCA II --- Ni-BTC nanorods --- metal–organic frameworks --- polyoxometalates --- hybrid materials --- synthesis --- catalysis --- heterogeneous catalyst --- aerobic oxidation --- cyclohexene --- metal organic frameworks --- NH2-MIL-125(Ti) --- water stability --- purification --- layered coordination polymer --- oxidative desulfurization --- denitrogenation extraction --- hydrogen peroxide --- lanthanides --- MOF --- catalyst --- microreactor --- kinetic studies --- metal organic frame works --- CO2 adsorption --- pre combustion --- gas membrane separation --- metal halide perovskites --- metal-organic framework --- fuel cell --- oxygen reduction reaction (ORR) --- metal organic frameworks (MOFs) --- hydrothermal synthesis --- coordination polymers --- crystal structures --- metal-organic frameworks --- carboxylate ligands --- olefin paraffin separations --- propyne --- propylene --- adsorption isotherms --- dynamic breakthrough --- n/a --- Metal-organic framework
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This reprint of “Metal Nanoparticles as Catalysts for Green Applications” collects recent works of researchers on metal nanoparticles as catalysts for green applications. All works deal with designing chemical products and processes that generate and use less (or preferably no) hazardous substances by applying the principles of green chemistry. Despite the interdisciplinary nature of the different applications involved, ranging from pure chemistry to material science, from chemical engineering to physical chemistry, in this reprint there are common characteristics connecting the areas together, and they can be described by two words: sustainability and catalysis.
Technology: general issues --- acetylene hydrogenation --- kinetic model --- catalyst decay --- process modeling --- Al2O3 --- bimetallic catalyst --- syngas --- methane --- partial oxidation --- ZrO2 --- metal–organic framework --- bimetallic metal–organic frameworks --- decarboxylative amidation --- polymeric catalytic membranes --- electrospinning --- HMF oxidation --- glucose --- biochemicals --- MCM-41 --- bimetallic --- reactivity --- product selectivity --- neem --- mint --- nZVI synthesis --- lead --- nickel --- soil remediation --- ethanol steam reforming --- Ni/CeO2 --- microemulsion --- coke resistance --- lanthanum doping --- hydrodeoxygenation --- guaiacol --- regeneration --- catalyst deactivation --- n/a --- metal-organic framework --- bimetallic metal-organic frameworks
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This reprint of “Metal Nanoparticles as Catalysts for Green Applications” collects recent works of researchers on metal nanoparticles as catalysts for green applications. All works deal with designing chemical products and processes that generate and use less (or preferably no) hazardous substances by applying the principles of green chemistry. Despite the interdisciplinary nature of the different applications involved, ranging from pure chemistry to material science, from chemical engineering to physical chemistry, in this reprint there are common characteristics connecting the areas together, and they can be described by two words: sustainability and catalysis.
Technology: general issues --- acetylene hydrogenation --- kinetic model --- catalyst decay --- process modeling --- Al2O3 --- bimetallic catalyst --- syngas --- methane --- partial oxidation --- ZrO2 --- metal–organic framework --- bimetallic metal–organic frameworks --- decarboxylative amidation --- polymeric catalytic membranes --- electrospinning --- HMF oxidation --- glucose --- biochemicals --- MCM-41 --- bimetallic --- reactivity --- product selectivity --- neem --- mint --- nZVI synthesis --- lead --- nickel --- soil remediation --- ethanol steam reforming --- Ni/CeO2 --- microemulsion --- coke resistance --- lanthanum doping --- hydrodeoxygenation --- guaiacol --- regeneration --- catalyst deactivation --- n/a --- metal-organic framework --- bimetallic metal-organic frameworks
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This reprint of “Metal Nanoparticles as Catalysts for Green Applications” collects recent works of researchers on metal nanoparticles as catalysts for green applications. All works deal with designing chemical products and processes that generate and use less (or preferably no) hazardous substances by applying the principles of green chemistry. Despite the interdisciplinary nature of the different applications involved, ranging from pure chemistry to material science, from chemical engineering to physical chemistry, in this reprint there are common characteristics connecting the areas together, and they can be described by two words: sustainability and catalysis.
acetylene hydrogenation --- kinetic model --- catalyst decay --- process modeling --- Al2O3 --- bimetallic catalyst --- syngas --- methane --- partial oxidation --- ZrO2 --- metal–organic framework --- bimetallic metal–organic frameworks --- decarboxylative amidation --- polymeric catalytic membranes --- electrospinning --- HMF oxidation --- glucose --- biochemicals --- MCM-41 --- bimetallic --- reactivity --- product selectivity --- neem --- mint --- nZVI synthesis --- lead --- nickel --- soil remediation --- ethanol steam reforming --- Ni/CeO2 --- microemulsion --- coke resistance --- lanthanum doping --- hydrodeoxygenation --- guaiacol --- regeneration --- catalyst deactivation --- n/a --- metal-organic framework --- bimetallic metal-organic frameworks
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