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The current book brings together the latest developments in the area of ionic liquids, including synthesis, purity control, toxicity, and scaling-up technologies. In addition, the authors explore the applications of ionic liquids in organic synthesis and catalysis, separation techniques and nanomaterials engineering. Written by key experts in the field, this book is an invaluable material for organic and green chemists in academia and industry.
Ionic solutions. --- Catalysis. --- Ionic Liquids. --- Nanomaterials. --- Scale-up Technologies. --- Separation Techniques. --- Synthesis. --- Toxicity.
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In this study, I analyze the requirements for supporting organization for the scale-up companies to growth in Luxembourg. These companies, which already have a Business Model, are ideally positioned to create value, growth and jobs. I investigate the current situation in some European countries, the advice from the works of literature, and the Luxembourgish support structure. With the learning from the prosperous countries, the literature and with the interview of several actors of the Luxembourg ecosystem, I propose some recommendations to support the scale-up growth in Luxembourg.
SCALE-UP --- GROWTH --- Entrepreneurship --- LUXEMBOURG --- MESO-LEVEL --- INNOVATION --- Sciences économiques & de gestion > Stratégie & innovation
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This Multiphase Reactors book is about fundamentals, selection, design, development (scale-up) and applications of two- and three-phase reactors. It is a graduate textbook focused on creating understanding of the fundamentals, as much as possible without resorting to mathematics. It also is full of real-life industrial applications and examples from the authors’ own experiences. The target audience comprises students and industrial practitioners who may or may not have had formal training in chemical reaction engineering. Each chapter explains the subject and contains take home messages, examples, worked out cases, quiz questions, and exercises.
Chemical Engineering. --- Chemical Reaction Engineering. --- Chemical Technology. --- Heat Transfer. --- Mass Transfer. --- Process Engineering. --- Reactor Selection. --- Residence-Time Distribution. --- Scale-up. --- Three-Phase Reactors.
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Process intensification aims for increasing efficiency and sustainability of (bio-)chemical production processes. This book presents strategies for improving fluid separation such as reactive distillation, reactive absorption and membrane assisted separations. The authors discuss computer simulation, model development, methodological approaches for synthesis and the design and scale-up of final industrial processes. Process intensification aims for increasing efficiency and sustainability of (bio-)chemical production processes. This book presents strategies for improving fluid separation such as reactive distillation, reactive absorption and membrane assisted separations. The authors discuss computer simulation, model development, methodological approaches for synthesis and the design and scale-up of the final industrial processes.
Chemical process control. --- Separation (Technology) --- Salvage (Waste, etc.) --- Membranes (Technology) --- Chemistry, Technical. --- Chemical technology --- Industrial chemistry --- Technical chemistry --- Chemistry --- Technology --- Chemical engineering --- Artificial membranes --- Conversion of waste products --- Industrial salvage --- Recovery of waste products --- Solid waste management --- Utilization of waste products --- Waste management --- Waste reclamation --- Waste products --- Recycling (Waste, etc.) --- Refuse and refuse disposal --- Analytical chemistry --- Chemistry, Technical --- Process control --- Chemical separations --- Separation processes --- Separation science --- Separation technologies --- Separations, Chemical --- Fluid separation. --- Process Intensification. --- Scale-Up. --- Sustainable Production Processes.
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Since the first works introducing the aluminum intercalated clay family in the early 1970s, interest in the synthesis of Pillared InterLayered Clays (PILC) has increased tremendously, especially research into their properties and energetic and environmental applications. After our comprehensive reviews and book on the synthesis and catalytic applications of these materials, new references have appeared in the literature and the interest in this field is continuously increasing. The aim of this Special Issue is to collect the recent advances developed considering this family of solids.
Technology: general issues --- clays --- Al-PILC --- pillared clays --- scale up --- pillaring solution --- Keggin ion --- reutilization --- Keggin polycation --- concentrated media --- microwave radiation --- pillared montmorillonite --- AlNi-PILC --- Pd-Ce --- catalytic combustion --- benzene --- TPD/TPSR --- ZnO-TiO2/delaminated montmorillonite --- heterostructures --- Ag-coating --- solar photocatalytic activity --- water purification --- cadmium --- chitosan --- modification --- 13X molecular sieve --- removal --- dye remediation --- adsorption --- azo dye --- wastewater --- pillared porous phosphate heterostructures --- isotherm --- sericite --- thermal modification --- acid activation --- sodium modification --- montmorillonite/hydrotalcite composite --- montmorillonite/titania composite --- organoclay --- inverse micelle --- Mn-Al mixed oxide --- combustion catalysts --- ciprofloxacin --- smectite --- pillared clay --- keggin-like mixed Al/Fe polyoxocation --- mineralogical composition --- catalytic wet peroxide oxidation --- mesosilica --- methyl orange --- palygorskite
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A rapid growth in various industries and domestic activities is resulting in a huge amount of wastewater. Various types of wastewaters, such as textile, municipal, dairy, pharmaceutical, swine, and aquaculture, etc., are produced regularly by respective industries. These wastewaters are rich in nutrient content and promote eutrophication in the ecosystem and pose a threat to flora and fauna. According to an estimate, eutrophication causes losses of almost 2 billion US dollars annually, affecting real estate and fishing activities. Treatment of wastewater is a costly process and recently wastewater treatment with simultaneous energy production has received more attention. Microorganisms can be used to recover nutrients from wastewater and produce bioenergy (biodiesel, biohydrogen, bioelectricity, methane, etc.). A better understanding of the composition of various types of wastewaters and the development of technologies like anaerobic digestion (AD), microbial fuel cell (MFC), and microbial electrolysis cell (MEC) can help to make wastewater-based biorefinery a reality. To provide an overall overview to students, teachers, and researchers on wastewater to bioenergy technology ten chapters are included in this book.
Environmental science, engineering & technology --- effluent --- anaerobic digestion --- incineration --- Co-pyrolysis --- syngas --- biodiesel --- biofuel --- biogas --- MEC --- bio-hydrogen --- manure --- digestion --- cybersecurity --- cybercrime --- legislation --- policy --- systems thinking --- water --- DEA --- regional difference --- energy utilization efficiency --- carbon emission --- cost --- database --- treatment --- wastewater --- Web of Science --- biogas digestion --- hydrogen sulfide --- ferric oxide --- waterworks sludge --- biofilm --- lattice Boltzmann method --- cellular automata --- individual-based model --- chitin --- electricity generation --- halotolerant --- microbial fuel cell --- seafood processing --- microbial electrolysis cells --- chronological development --- wastewater to hydrogen --- scale-up --- life-cycle assessment --- MEC commercialization --- microalgae --- wastewater treatment --- nutrient removal --- n/a
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Since the first works introducing the aluminum intercalated clay family in the early 1970s, interest in the synthesis of Pillared InterLayered Clays (PILC) has increased tremendously, especially research into their properties and energetic and environmental applications. After our comprehensive reviews and book on the synthesis and catalytic applications of these materials, new references have appeared in the literature and the interest in this field is continuously increasing. The aim of this Special Issue is to collect the recent advances developed considering this family of solids.
clays --- Al-PILC --- pillared clays --- scale up --- pillaring solution --- Keggin ion --- reutilization --- Keggin polycation --- concentrated media --- microwave radiation --- pillared montmorillonite --- AlNi-PILC --- Pd-Ce --- catalytic combustion --- benzene --- TPD/TPSR --- ZnO-TiO2/delaminated montmorillonite --- heterostructures --- Ag-coating --- solar photocatalytic activity --- water purification --- cadmium --- chitosan --- modification --- 13X molecular sieve --- removal --- dye remediation --- adsorption --- azo dye --- wastewater --- pillared porous phosphate heterostructures --- isotherm --- sericite --- thermal modification --- acid activation --- sodium modification --- montmorillonite/hydrotalcite composite --- montmorillonite/titania composite --- organoclay --- inverse micelle --- Mn-Al mixed oxide --- combustion catalysts --- ciprofloxacin --- smectite --- pillared clay --- keggin-like mixed Al/Fe polyoxocation --- mineralogical composition --- catalytic wet peroxide oxidation --- mesosilica --- methyl orange --- palygorskite
Choose an application
A rapid growth in various industries and domestic activities is resulting in a huge amount of wastewater. Various types of wastewaters, such as textile, municipal, dairy, pharmaceutical, swine, and aquaculture, etc., are produced regularly by respective industries. These wastewaters are rich in nutrient content and promote eutrophication in the ecosystem and pose a threat to flora and fauna. According to an estimate, eutrophication causes losses of almost 2 billion US dollars annually, affecting real estate and fishing activities. Treatment of wastewater is a costly process and recently wastewater treatment with simultaneous energy production has received more attention. Microorganisms can be used to recover nutrients from wastewater and produce bioenergy (biodiesel, biohydrogen, bioelectricity, methane, etc.). A better understanding of the composition of various types of wastewaters and the development of technologies like anaerobic digestion (AD), microbial fuel cell (MFC), and microbial electrolysis cell (MEC) can help to make wastewater-based biorefinery a reality. To provide an overall overview to students, teachers, and researchers on wastewater to bioenergy technology ten chapters are included in this book.
effluent --- anaerobic digestion --- incineration --- Co-pyrolysis --- syngas --- biodiesel --- biofuel --- biogas --- MEC --- bio-hydrogen --- manure --- digestion --- cybersecurity --- cybercrime --- legislation --- policy --- systems thinking --- water --- DEA --- regional difference --- energy utilization efficiency --- carbon emission --- cost --- database --- treatment --- wastewater --- Web of Science --- biogas digestion --- hydrogen sulfide --- ferric oxide --- waterworks sludge --- biofilm --- lattice Boltzmann method --- cellular automata --- individual-based model --- chitin --- electricity generation --- halotolerant --- microbial fuel cell --- seafood processing --- microbial electrolysis cells --- chronological development --- wastewater to hydrogen --- scale-up --- life-cycle assessment --- MEC commercialization --- microalgae --- wastewater treatment --- nutrient removal --- n/a
Choose an application
A rapid growth in various industries and domestic activities is resulting in a huge amount of wastewater. Various types of wastewaters, such as textile, municipal, dairy, pharmaceutical, swine, and aquaculture, etc., are produced regularly by respective industries. These wastewaters are rich in nutrient content and promote eutrophication in the ecosystem and pose a threat to flora and fauna. According to an estimate, eutrophication causes losses of almost 2 billion US dollars annually, affecting real estate and fishing activities. Treatment of wastewater is a costly process and recently wastewater treatment with simultaneous energy production has received more attention. Microorganisms can be used to recover nutrients from wastewater and produce bioenergy (biodiesel, biohydrogen, bioelectricity, methane, etc.). A better understanding of the composition of various types of wastewaters and the development of technologies like anaerobic digestion (AD), microbial fuel cell (MFC), and microbial electrolysis cell (MEC) can help to make wastewater-based biorefinery a reality. To provide an overall overview to students, teachers, and researchers on wastewater to bioenergy technology ten chapters are included in this book.
Environmental science, engineering & technology --- effluent --- anaerobic digestion --- incineration --- Co-pyrolysis --- syngas --- biodiesel --- biofuel --- biogas --- MEC --- bio-hydrogen --- manure --- digestion --- cybersecurity --- cybercrime --- legislation --- policy --- systems thinking --- water --- DEA --- regional difference --- energy utilization efficiency --- carbon emission --- cost --- database --- treatment --- wastewater --- Web of Science --- biogas digestion --- hydrogen sulfide --- ferric oxide --- waterworks sludge --- biofilm --- lattice Boltzmann method --- cellular automata --- individual-based model --- chitin --- electricity generation --- halotolerant --- microbial fuel cell --- seafood processing --- microbial electrolysis cells --- chronological development --- wastewater to hydrogen --- scale-up --- life-cycle assessment --- MEC commercialization --- microalgae --- wastewater treatment --- nutrient removal --- effluent --- anaerobic digestion --- incineration --- Co-pyrolysis --- syngas --- biodiesel --- biofuel --- biogas --- MEC --- bio-hydrogen --- manure --- digestion --- cybersecurity --- cybercrime --- legislation --- policy --- systems thinking --- water --- DEA --- regional difference --- energy utilization efficiency --- carbon emission --- cost --- database --- treatment --- wastewater --- Web of Science --- biogas digestion --- hydrogen sulfide --- ferric oxide --- waterworks sludge --- biofilm --- lattice Boltzmann method --- cellular automata --- individual-based model --- chitin --- electricity generation --- halotolerant --- microbial fuel cell --- seafood processing --- microbial electrolysis cells --- chronological development --- wastewater to hydrogen --- scale-up --- life-cycle assessment --- MEC commercialization --- microalgae --- wastewater treatment --- nutrient removal
Choose an application
Since the first works introducing the aluminum intercalated clay family in the early 1970s, interest in the synthesis of Pillared InterLayered Clays (PILC) has increased tremendously, especially research into their properties and energetic and environmental applications. After our comprehensive reviews and book on the synthesis and catalytic applications of these materials, new references have appeared in the literature and the interest in this field is continuously increasing. The aim of this Special Issue is to collect the recent advances developed considering this family of solids.
Technology: general issues --- clays --- Al-PILC --- pillared clays --- scale up --- pillaring solution --- Keggin ion --- reutilization --- Keggin polycation --- concentrated media --- microwave radiation --- pillared montmorillonite --- AlNi-PILC --- Pd-Ce --- catalytic combustion --- benzene --- TPD/TPSR --- ZnO-TiO2/delaminated montmorillonite --- heterostructures --- Ag-coating --- solar photocatalytic activity --- water purification --- cadmium --- chitosan --- modification --- 13X molecular sieve --- removal --- dye remediation --- adsorption --- azo dye --- wastewater --- pillared porous phosphate heterostructures --- isotherm --- sericite --- thermal modification --- acid activation --- sodium modification --- montmorillonite/hydrotalcite composite --- montmorillonite/titania composite --- organoclay --- inverse micelle --- Mn-Al mixed oxide --- combustion catalysts --- ciprofloxacin --- smectite --- pillared clay --- keggin-like mixed Al/Fe polyoxocation --- mineralogical composition --- catalytic wet peroxide oxidation --- mesosilica --- methyl orange --- palygorskite --- clays --- Al-PILC --- pillared clays --- scale up --- pillaring solution --- Keggin ion --- reutilization --- Keggin polycation --- concentrated media --- microwave radiation --- pillared montmorillonite --- AlNi-PILC --- Pd-Ce --- catalytic combustion --- benzene --- TPD/TPSR --- ZnO-TiO2/delaminated montmorillonite --- heterostructures --- Ag-coating --- solar photocatalytic activity --- water purification --- cadmium --- chitosan --- modification --- 13X molecular sieve --- removal --- dye remediation --- adsorption --- azo dye --- wastewater --- pillared porous phosphate heterostructures --- isotherm --- sericite --- thermal modification --- acid activation --- sodium modification --- montmorillonite/hydrotalcite composite --- montmorillonite/titania composite --- organoclay --- inverse micelle --- Mn-Al mixed oxide --- combustion catalysts --- ciprofloxacin --- smectite --- pillared clay --- keggin-like mixed Al/Fe polyoxocation --- mineralogical composition --- catalytic wet peroxide oxidation --- mesosilica --- methyl orange --- palygorskite
Listing 1 - 10 of 31 | << page >> |
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