FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3163993452> ?p ?o ?g. }

• W3163993452 endingPage "673" @default.
• W3163993452 startingPage "660" @default.
• W3163993452 abstract "Ammonia is a promising hydrogen carrier due to its high volumetric energy density and ease of liquefication under mild conditions, thus circumventing the safety and transportation issues of hydrogen. To couple the utilization of ammonia with renewable powers, it is essential to develop stable and efficient catalysts for ammonia synthesis and decomposition under mild conditions. New strategies in catalyst design need to be devised to address hydrogen poisoning, scaling limitations, and slow kinetics issues in renewable N-cycle catalysis under mild conditions. N-cycle catalysis featuring the recycling of nitrogen with hydrogen in a chemical process could exert a profound impact on human society for the eventual sustainable production of foods, chemicals, and fuels. The challenges for materials required to perform efficient catalysis to activate N2 and renewable H2 to NH3 and for the reversible reaction to facilitate the storage and transport of renewable energies, in addition to coupling with fuel cells, are of paramount importance. In this review, we highlight and discuss the importance of the diverse position of NH3 as a fuel, fertilizer, and chemical vector. This review also provides an overview of the recent developments in ammonia synthesis and the decomposition of some promising materials and their prospects in these new processes. N-cycle catalysis featuring the recycling of nitrogen with hydrogen in a chemical process could exert a profound impact on human society for the eventual sustainable production of foods, chemicals, and fuels. The challenges for materials required to perform efficient catalysis to activate N2 and renewable H2 to NH3 and for the reversible reaction to facilitate the storage and transport of renewable energies, in addition to coupling with fuel cells, are of paramount importance. In this review, we highlight and discuss the importance of the diverse position of NH3 as a fuel, fertilizer, and chemical vector. This review also provides an overview of the recent developments in ammonia synthesis and the decomposition of some promising materials and their prospects in these new processes. a synergistic orbital interaction between a transition metal and a pi-conjugated ligand. a kind of gas-surface adsorption that leads to the dissociation of a diatomic molecule. a class of ionic compounds where electrons serve as anions. the ‘green alternative’ to the traditional HB process where brown hydrogen generated from steam reforming is replaced by green hydrogen generated from electrolysis of water from renewables. the highly energy-intensive industrial production of ammonia that occurs at 500°C and 250 bar, producing a tremendous amount of CO2 and consuming more than 1% of global energy every year. a phenomenon where metal active sites on a catalyst are blocked by adsorbed H atoms. the slowest step in a chemical reaction that determines the overall rate of the reaction process. a type of plot with an inverted V-shape describing the ‘ideal’ adsorption interaction between a catalyst and a substrate." @default.
• W3163993452 created "2021-06-07" @default.
• W3163993452 creator A5058130044 @default.
• W3163993452 creator A5091670688 @default.
• W3163993452 date "2021-08-01" @default.
• W3163993452 modified "2023-10-02" @default.
• W3163993452 title "Renewable N-cycle catalysis" @default.
• W3163993452 cites W103211297 @default.
• W3163993452 cites W1586460101 @default.
• W3163993452 cites W1618810017 @default.
• W3163993452 cites W1965606835 @default.
• W3163993452 cites W1969141512 @default.
• W3163993452 cites W1971425140 @default.
• W3163993452 cites W1976129612 @default.
• W3163993452 cites W1977956754 @default.
• W3163993452 cites W1980072692 @default.
• W3163993452 cites W1981657121 @default.
• W3163993452 cites W1988846397 @default.
• W3163993452 cites W1992023766 @default.
• W3163993452 cites W1995957208 @default.
• W3163993452 cites W1997060154 @default.
• W3163993452 cites W1997721562 @default.
• W3163993452 cites W2009623205 @default.
• W3163993452 cites W2010528269 @default.
• W3163993452 cites W2010571276 @default.
• W3163993452 cites W2016680759 @default.
• W3163993452 cites W2020600458 @default.
• W3163993452 cites W2034376552 @default.
• W3163993452 cites W2044055975 @default.
• W3163993452 cites W2056823453 @default.
• W3163993452 cites W2065728156 @default.
• W3163993452 cites W2071895782 @default.
• W3163993452 cites W2073991299 @default.
• W3163993452 cites W2074240540 @default.
• W3163993452 cites W2078776027 @default.
• W3163993452 cites W2078888613 @default.
• W3163993452 cites W2082361355 @default.
• W3163993452 cites W2089381369 @default.
• W3163993452 cites W2090914975 @default.
• W3163993452 cites W2091661163 @default.
• W3163993452 cites W2097177939 @default.
• W3163993452 cites W2105081100 @default.
• W3163993452 cites W2108445769 @default.
• W3163993452 cites W2117699876 @default.
• W3163993452 cites W2126482965 @default.
• W3163993452 cites W2133099634 @default.
• W3163993452 cites W2159779672 @default.
• W3163993452 cites W2296375572 @default.
• W3163993452 cites W2510877666 @default.
• W3163993452 cites W2513715114 @default.
• W3163993452 cites W2516604642 @default.
• W3163993452 cites W2523397185 @default.
• W3163993452 cites W2607558876 @default.
• W3163993452 cites W2621030767 @default.
• W3163993452 cites W2783103484 @default.
• W3163993452 cites W2794577885 @default.
• W3163993452 cites W2795523966 @default.
• W3163993452 cites W2803852160 @default.
• W3163993452 cites W2811251786 @default.
• W3163993452 cites W2907616322 @default.
• W3163993452 cites W2909956549 @default.
• W3163993452 cites W2911326591 @default.
• W3163993452 cites W2911469374 @default.
• W3163993452 cites W2940084201 @default.
• W3163993452 cites W2944156152 @default.
• W3163993452 cites W2953194890 @default.
• W3163993452 cites W2953339658 @default.
• W3163993452 cites W2972052805 @default.
• W3163993452 cites W2975691016 @default.
• W3163993452 cites W2982051913 @default.
• W3163993452 cites W2998496658 @default.
• W3163993452 cites W3003110488 @default.
• W3163993452 cites W3017189000 @default.
• W3163993452 cites W3024047201 @default.
• W3163993452 cites W3039210145 @default.
• W3163993452 cites W3042335072 @default.
• W3163993452 cites W3046677587 @default.
• W3163993452 cites W3113090012 @default.
• W3163993452 cites W4242609961 @default.
• W3163993452 cites W4378174013 @default.
• W3163993452 cites W68147292 @default.
• W3163993452 doi "https://doi.org/10.1016/j.trechm.2021.04.010" @default.
• W3163993452 hasPublicationYear "2021" @default.
• W3163993452 type Work @default.
• W3163993452 sameAs 3163993452 @default.
• W3163993452 citedByCount "7" @default.
• W3163993452 countsByYear W31639934522022 @default.
• W3163993452 countsByYear W31639934522023 @default.
• W3163993452 crossrefType "journal-article" @default.
• W3163993452 hasAuthorship W3163993452A5058130044 @default.
• W3163993452 hasAuthorship W3163993452A5091670688 @default.
• W3163993452 hasConcept C119599485 @default.
• W3163993452 hasConcept C127413603 @default.
• W3163993452 hasConcept C161790260 @default.
• W3163993452 hasConcept C178790620 @default.
• W3163993452 hasConcept C181258405 @default.
• W3163993452 hasConcept C183696295 @default.
• W3163993452 hasConcept C185592680 @default.

• next