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Propylene oxide --- Environmental aspects. --- Physiological effect. --- Toxicology.
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Propylene oxide --- Waste spills --- Environmental aspects --- Environmental aspects
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Pressurized water reactors --- Nuclear reactors --- Ethylene-propylene rubber. --- Loss of coolant. --- Materials --- Testing.
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Pressurized water reactors --- Nuclear reactors --- Ethylene-propylene rubber. --- Loss of coolant. --- Materials --- Testing.
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Fully revised and updated, Processing Contaminants in Edible Oils, 2nd edition, presents the latest research on monochloropropanediol (MCPD) and glycidyl esters in edible oils. These potentially harmful contaminants are formed during the industrial processing of food oils during deodorization. A number of advancements in understanding these have been made since the publication of the first edition. These important changes, which impact industrial mitigation, analytical methods, toxicology and regulation, are highlighted for up-to-date reference. The mechanisms of formation for MCPD and glycidyl ester contaminants, as well as research identifying possible precursor molecules are reviewed, as are strategies which have been used successfully to decrease the concentrations of these contaminants. From the removal of precursor molecules before processing, modifications of deodorization protocol, to approaches for the removal of these contaminants after the completion of processing, methods of mitigating and eliminating contaminants are presented.
Oils and fats, Edible --- Deterioration. --- Deterioration of edible oils and fats --- Food contamination. --- Food Contamination --- Propylene Glycols --- Propanols
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Propylene oxide --- Epoxy Compounds --- Toxicology --- Environmental aspects --- adverse effects --- toxicity --- Chemical spills --- Ethylene oxide --- Handbooks, manuals, etc
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Palladium (Pd)-based membranes have received a great deal of attention from both academia and industry thanks to their ability to selectively separate hydrogen from gas streams. The integration of such membranes with appropriate catalysts in membrane reactors allows for hydrogen production with CO2 capture that can be applied in smaller bioenergy or combined heat and power (CHP) plants, as well as in large-scale power plants. Pd-based membranes are therefore regarded as a Key Enabling Technology (KET) to facilitate the transition towards a knowledge-based, low-carbon, and resource-efficient economy. This Special Issue of the journal Membranes on “Pd-based Membranes: Overview and Perspectives” contains nine peer-reviewed articles. Topics include manufacturing techniques, understanding of material phenomena, module and reactor design, novel applications, and demonstration efforts and industrial exploitation.
hydrides --- membrane --- Pd-Ag membranes --- electroless plating --- defect distribution --- hydrogen --- hydrogen production --- suspension plasma spraying --- chemical potential --- review --- grain boundary --- manufacturing --- palladium --- LOHC --- palladium alloy --- open architecture --- PdAg-membrane --- hydrogen permeation --- modelling --- membranes --- pore mouth size distribution --- MLLDP --- solubility --- closed architecture --- demonstration --- Pd-based membrane --- methanol steam reforming --- activity --- micro reactor --- microstructured --- hydrogen separation --- membrane reactors --- Pd alloy --- hydrogen purification --- palladium-based membrane --- gas to liquid --- dense Pd membrane --- propylene --- heat treatment --- surface characterization --- porous membrane --- multi-stage --- membrane reactor --- dehydrogenation
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Palladium (Pd)-based membranes have received a great deal of attention from both academia and industry thanks to their ability to selectively separate hydrogen from gas streams. The integration of such membranes with appropriate catalysts in membrane reactors allows for hydrogen production with CO2 capture that can be applied in smaller bioenergy or combined heat and power (CHP) plants, as well as in large-scale power plants. Pd-based membranes are therefore regarded as a Key Enabling Technology (KET) to facilitate the transition towards a knowledge-based, low-carbon, and resource-efficient economy. This Special Issue of the journal Membranes on “Pd-based Membranes: Overview and Perspectives” contains nine peer-reviewed articles. Topics include manufacturing techniques, understanding of material phenomena, module and reactor design, novel applications, and demonstration efforts and industrial exploitation.
hydrides --- membrane --- Pd-Ag membranes --- electroless plating --- defect distribution --- hydrogen --- hydrogen production --- suspension plasma spraying --- chemical potential --- review --- grain boundary --- manufacturing --- palladium --- LOHC --- palladium alloy --- open architecture --- PdAg-membrane --- hydrogen permeation --- modelling --- membranes --- pore mouth size distribution --- MLLDP --- solubility --- closed architecture --- demonstration --- Pd-based membrane --- methanol steam reforming --- activity --- micro reactor --- microstructured --- hydrogen separation --- membrane reactors --- Pd alloy --- hydrogen purification --- palladium-based membrane --- gas to liquid --- dense Pd membrane --- propylene --- heat treatment --- surface characterization --- porous membrane --- multi-stage --- membrane reactor --- dehydrogenation
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Palladium (Pd)-based membranes have received a great deal of attention from both academia and industry thanks to their ability to selectively separate hydrogen from gas streams. The integration of such membranes with appropriate catalysts in membrane reactors allows for hydrogen production with CO2 capture that can be applied in smaller bioenergy or combined heat and power (CHP) plants, as well as in large-scale power plants. Pd-based membranes are therefore regarded as a Key Enabling Technology (KET) to facilitate the transition towards a knowledge-based, low-carbon, and resource-efficient economy. This Special Issue of the journal Membranes on “Pd-based Membranes: Overview and Perspectives” contains nine peer-reviewed articles. Topics include manufacturing techniques, understanding of material phenomena, module and reactor design, novel applications, and demonstration efforts and industrial exploitation.
hydrides --- membrane --- Pd-Ag membranes --- electroless plating --- defect distribution --- hydrogen --- hydrogen production --- suspension plasma spraying --- chemical potential --- review --- grain boundary --- manufacturing --- palladium --- LOHC --- palladium alloy --- open architecture --- PdAg-membrane --- hydrogen permeation --- modelling --- membranes --- pore mouth size distribution --- MLLDP --- solubility --- closed architecture --- demonstration --- Pd-based membrane --- methanol steam reforming --- activity --- micro reactor --- microstructured --- hydrogen separation --- membrane reactors --- Pd alloy --- hydrogen purification --- palladium-based membrane --- gas to liquid --- dense Pd membrane --- propylene --- heat treatment --- surface characterization --- porous membrane --- multi-stage --- membrane reactor --- dehydrogenation
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