00855cam0-22003251i-450-99000641515040332120050905142851.0000641515FED01000641515(Aleph)000641515FED0100064151520001002d1963----km-y0itay50------baitaITy-------001yy<<La >>scoperta dell'ItaliaGiorgio BoccaBariLaterza1963481 p.24 cmLibri del tempo Laterza8114340Bocca,Giorgio<1920-2011>126030ITUNINARICAUNIMARCBK990006415150403321BIB. BAT.10765249BAT14340 BOC029172SESBATSESScoperta dell'Italia649176UNINA02770nam 22003613a 450 991076578490332120250203235425.09783038977032303897703910.3390/books978-3-03897-703-2(CKB)5400000000000006(ScCtBLL)fb125117-b725-47d8-9773-16038772611c(OCoLC)1105805224(EXLCZ)99540000000000000620250203i20192019 uu enguru||||||||||txtrdacontentcrdamediacrrdacarrierPd-based Membranes : Overview and Perspectives /Thijs Peters, Alessio CaravellaBasel, Switzerland :MDPI,2019.1 online resource (1 p.)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.review; palladium; membrane; Pd alloy; electroless plating; membrane reactor; hydrogen separation; hydrogen production; MLLDP; porous membrane; pore mouth size distribution; dense Pd membrane; defect distribution; methanol steam reforming; hydrogen production; modelling; membrane reactors; membrane; hydrogen; palladium alloy; grain boundary; chemical potential; activity; hydrides; solubility; membranes; Pd-Ag membranes; hydrogen permeation; surface characterization; solubility; heat treatment; Pd-based membrane; hydrogen; closed architecture; open architecture; gas to liquid; propylene; membrane reactor; hydrogen; palladium; microstructured; LOHC; suspension plasma spraying; LOHC; dehydrogenation; multi-stage; PdAg-membrane; micro reactor; hydrogen purification; palladium-based membrane; hydrogen; manufacturing; demonstrationPeters Thijs1296339Caravella AlessioScCtBLLScCtBLLBOOK9910765784903321Pd-based Membranes4322339UNINA