TY - BOOK ID - 145189879 TI - Pd-based Membranes. Overview and Perspectives AU - Peters, Thijs AU - Caravella, Alessio PY - 2019 PB - MDPI - Multidisciplinary Digital Publishing Institute DB - UniCat KW - hydrides KW - membrane KW - Pd-Ag membranes KW - electroless plating KW - defect distribution KW - hydrogen KW - hydrogen production KW - suspension plasma spraying KW - chemical potential KW - review KW - grain boundary KW - manufacturing KW - palladium KW - LOHC KW - palladium alloy KW - open architecture KW - PdAg-membrane KW - hydrogen permeation KW - modelling KW - membranes KW - pore mouth size distribution KW - MLLDP KW - solubility KW - closed architecture KW - demonstration KW - Pd-based membrane KW - methanol steam reforming KW - activity KW - micro reactor KW - microstructured KW - hydrogen separation KW - membrane reactors KW - Pd alloy KW - hydrogen purification KW - palladium-based membrane KW - gas to liquid KW - dense Pd membrane KW - propylene KW - heat treatment KW - surface characterization KW - porous membrane KW - multi-stage KW - membrane reactor KW - dehydrogenation KW - hydrides KW - membrane KW - Pd-Ag membranes KW - electroless plating KW - defect distribution KW - hydrogen KW - hydrogen production KW - suspension plasma spraying KW - chemical potential KW - review KW - grain boundary KW - manufacturing KW - palladium KW - LOHC KW - palladium alloy KW - open architecture KW - PdAg-membrane KW - hydrogen permeation KW - modelling KW - membranes KW - pore mouth size distribution KW - MLLDP KW - solubility KW - closed architecture KW - demonstration KW - Pd-based membrane KW - methanol steam reforming KW - activity KW - micro reactor KW - microstructured KW - hydrogen separation KW - membrane reactors KW - Pd alloy KW - hydrogen purification KW - palladium-based membrane KW - gas to liquid KW - dense Pd membrane KW - propylene KW - heat treatment KW - surface characterization KW - porous membrane KW - multi-stage KW - membrane reactor KW - dehydrogenation UR - https://www.unicat.be/uniCat?func=search&query=sysid:145189879 AB - 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. ER -