SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4285113089> ?p ?o ?g. }

Showing items 1 to 100 of ±150 with 100 items per page.

W4285113089 endingPage "407" @default.
W4285113089 startingPage "377" @default.
W4285113089 abstract "Hydrogen, the lightest element on our parent earth with high specific energy density of 142 MJ/kg, promises to be one of the potential energy carriers for a sustainable energy future. Today over 96% of the hydrogen is produced from thermocatalytic steam methane reforming (SMR) process, which is commonly referred to as “gray hydrogen.” The SMR process highly relies on finite fossil-fuel resources, and the high carbon intensity of the process impedes its applicability in sustainable energy system. Alternatively, low carbon hydrogen can be produced from photocatalytic and electrocatalytic water splitting process, which is commonly referred as “green hydrogen.” Despite significant efforts, the efficiency of photocatalytic water splitting remains low for any near-term application in commercial scale. In contrast, electrocatalytic water splitting has been quite successful and today water electrolyzers are commercially available for small to large scale applications. However, commercial water electrolyzers remain energy intensive due to the high overpotential requirements for the hydrogen and oxygen evolution reactions. In this context, there has been significant R&D to develop highly active electrocatalysts including transition metal-based sulfides and selenides etc. for green hydrogen production. This chapter focuses on various hydrogen production technologies and elaborates electrocatalytic way of hydrogen production by highlighting its applicability as a future energy carrier." @default.
W4285113089 created "2022-07-14" @default.
W4285113089 creator A5011750802 @default.
W4285113089 creator A5067628877 @default.
W4285113089 creator A5089695229 @default.
W4285113089 date "2022-01-01" @default.
W4285113089 modified "2023-09-25" @default.
W4285113089 title "Role of hydrogen generation technologies for renewable hydrogen production" @default.
W4285113089 cites W1923680886 @default.
W4285113089 cites W1969243292 @default.
W4285113089 cites W2011897791 @default.
W4285113089 cites W2012136380 @default.
W4285113089 cites W2017670421 @default.
W4285113089 cites W2020007931 @default.
W4285113089 cites W2020080291 @default.
W4285113089 cites W2032100925 @default.
W4285113089 cites W2042050383 @default.
W4285113089 cites W2043775186 @default.
W4285113089 cites W2045587961 @default.
W4285113089 cites W2058814771 @default.
W4285113089 cites W2076389245 @default.
W4285113089 cites W2105708469 @default.
W4285113089 cites W2118976774 @default.
W4285113089 cites W2124157224 @default.
W4285113089 cites W2159178552 @default.
W4285113089 cites W2168429268 @default.
W4285113089 cites W2171613439 @default.
W4285113089 cites W2200789076 @default.
W4285113089 cites W2212270013 @default.
W4285113089 cites W2287936852 @default.
W4285113089 cites W2294392547 @default.
W4285113089 cites W2322587632 @default.
W4285113089 cites W2409931918 @default.
W4285113089 cites W2471589050 @default.
W4285113089 cites W2473591459 @default.
W4285113089 cites W2489949788 @default.
W4285113089 cites W2534297795 @default.
W4285113089 cites W2534928601 @default.
W4285113089 cites W2571365432 @default.
W4285113089 cites W2725424529 @default.
W4285113089 cites W2747445000 @default.
W4285113089 cites W2750851534 @default.
W4285113089 cites W2755269103 @default.
W4285113089 cites W2767670999 @default.
W4285113089 cites W2771049031 @default.
W4285113089 cites W2782904998 @default.
W4285113089 cites W2853934268 @default.
W4285113089 cites W2900978566 @default.
W4285113089 cites W2903602303 @default.
W4285113089 cites W2911308343 @default.
W4285113089 cites W2980847753 @default.
W4285113089 cites W2982303614 @default.
W4285113089 cites W3020914782 @default.
W4285113089 cites W3032444046 @default.
W4285113089 cites W3080495354 @default.
W4285113089 cites W3087732979 @default.
W4285113089 cites W3095524834 @default.
W4285113089 cites W3110716500 @default.
W4285113089 cites W3112551702 @default.
W4285113089 cites W3126805880 @default.
W4285113089 doi "https://doi.org/10.1016/b978-0-323-99860-4.00023-x" @default.
W4285113089 hasPublicationYear "2022" @default.
W4285113089 type Work @default.
W4285113089 citedByCount "0" @default.
W4285113089 crossrefType "book-chapter" @default.
W4285113089 hasAuthorship W4285113089A5011750802 @default.
W4285113089 hasAuthorship W4285113089A5067628877 @default.
W4285113089 hasAuthorship W4285113089A5089695229 @default.
W4285113089 hasConcept C119599485 @default.
W4285113089 hasConcept C127413603 @default.
W4285113089 hasConcept C135473242 @default.
W4285113089 hasConcept C147789679 @default.
W4285113089 hasConcept C151730666 @default.
W4285113089 hasConcept C161790260 @default.
W4285113089 hasConcept C163127949 @default.
W4285113089 hasConcept C17525397 @default.
W4285113089 hasConcept C178790620 @default.
W4285113089 hasConcept C185592680 @default.
W4285113089 hasConcept C186460083 @default.
W4285113089 hasConcept C188573790 @default.
W4285113089 hasConcept C192562407 @default.
W4285113089 hasConcept C202189072 @default.
W4285113089 hasConcept C21880701 @default.
W4285113089 hasConcept C2779343474 @default.
W4285113089 hasConcept C35590869 @default.
W4285113089 hasConcept C39380314 @default.
W4285113089 hasConcept C39432304 @default.
W4285113089 hasConcept C43535742 @default.
W4285113089 hasConcept C48256821 @default.
W4285113089 hasConcept C512968161 @default.
W4285113089 hasConcept C52859227 @default.
W4285113089 hasConcept C542482507 @default.
W4285113089 hasConcept C548081761 @default.
W4285113089 hasConcept C55493867 @default.
W4285113089 hasConcept C65165184 @default.
W4285113089 hasConcept C68189081 @default.
W4285113089 hasConcept C68801617 @default.
W4285113089 hasConcept C7453809 @default.