SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3087402783> ?p ?o ?g. }

Showing items 1 to 100 of ±157 with 100 items per page.

W3087402783 endingPage "137113" @default.
W3087402783 startingPage "137113" @default.
W3087402783 abstract "Hydrogen from water splitting is one of the most promising alternatives for fossil fuels in solving the global energy crisis, while its electrochemical reaction mechanism, especially in liquid electrolytes, remains unclear. Herein, how the electrode conductivity affects the reaction sites of oxygen evolution reactions (OERs) in acidic and alkaline solutions was investigated by employing visualization system and electrochemical testing. Inserting Au nanolayers greatly increased electrode conductivities, improved OER kinetics and reduced cell ohmic resistance, leading to excellent water splitting performances in both acidic and alkaline electrolytes. Furthermore, the in-situ visualization results showed more reaction sites and higher catalyst utilizations were achieved by augmenting the electrode conductivity, and reaction sites increased from 1-dimension to 2-dimension. It was discovered that electrical conductivities of acidic and alkaline solutions are insufficient to overcome the sharp drop of potential in the electrical double layer for activating OER uniformly on low-conductivity catalysts, indicating the importance of electrical conductivity of the electrode in acidic and alkaline water electrolyzers. This study provided a guidance on how to develop efficient and compact electrodes for acidic and alkaline water electrolyzer stacks and other electrochemical devices, such as fuel cell, N2 reduction, CO2 conversion, etc." @default.
W3087402783 created "2020-09-25" @default.
W3087402783 creator A5030059719 @default.
W3087402783 creator A5035440542 @default.
W3087402783 creator A5049293174 @default.
W3087402783 creator A5053882650 @default.
W3087402783 creator A5067301238 @default.
W3087402783 creator A5068791597 @default.
W3087402783 creator A5077701818 @default.
W3087402783 creator A5080311794 @default.
W3087402783 date "2020-12-01" @default.
W3087402783 modified "2023-09-27" @default.
W3087402783 title "Role of electron pathway in dimensionally increasing water splitting reaction sites in liquid electrolytes" @default.
W3087402783 cites W1972673502 @default.
W3087402783 cites W1976204697 @default.
W3087402783 cites W1976887601 @default.
W3087402783 cites W1996774425 @default.
W3087402783 cites W1999502246 @default.
W3087402783 cites W2016580061 @default.
W3087402783 cites W2020007931 @default.
W3087402783 cites W2025611237 @default.
W3087402783 cites W2029128421 @default.
W3087402783 cites W2031302556 @default.
W3087402783 cites W2032267552 @default.
W3087402783 cites W2037145636 @default.
W3087402783 cites W2037733696 @default.
W3087402783 cites W2042438728 @default.
W3087402783 cites W2042663880 @default.
W3087402783 cites W2048717460 @default.
W3087402783 cites W2068697781 @default.
W3087402783 cites W2075705701 @default.
W3087402783 cites W2081728128 @default.
W3087402783 cites W2087059155 @default.
W3087402783 cites W2087538975 @default.
W3087402783 cites W2089322208 @default.
W3087402783 cites W2102333679 @default.
W3087402783 cites W2114291507 @default.
W3087402783 cites W2120037314 @default.
W3087402783 cites W2134194238 @default.
W3087402783 cites W2182351320 @default.
W3087402783 cites W2318317714 @default.
W3087402783 cites W2337358393 @default.
W3087402783 cites W2343186665 @default.
W3087402783 cites W2417963838 @default.
W3087402783 cites W2464190489 @default.
W3087402783 cites W2530477282 @default.
W3087402783 cites W2554030914 @default.
W3087402783 cites W2558998316 @default.
W3087402783 cites W2559852981 @default.
W3087402783 cites W2573377826 @default.
W3087402783 cites W2575797756 @default.
W3087402783 cites W2575823937 @default.
W3087402783 cites W2586200100 @default.
W3087402783 cites W2591485117 @default.
W3087402783 cites W2611414686 @default.
W3087402783 cites W2620815969 @default.
W3087402783 cites W2737033326 @default.
W3087402783 cites W2747241902 @default.
W3087402783 cites W2762833272 @default.
W3087402783 cites W2778710444 @default.
W3087402783 cites W2788989978 @default.
W3087402783 cites W2790329330 @default.
W3087402783 cites W2794349968 @default.
W3087402783 cites W2795932993 @default.
W3087402783 cites W2797491496 @default.
W3087402783 cites W2797640198 @default.
W3087402783 cites W2801649755 @default.
W3087402783 cites W2804788768 @default.
W3087402783 cites W2903072898 @default.
W3087402783 cites W2907483628 @default.
W3087402783 cites W2907860825 @default.
W3087402783 cites W2908136266 @default.
W3087402783 cites W2910889009 @default.
W3087402783 cites W2989864659 @default.
W3087402783 cites W3017375518 @default.
W3087402783 cites W4249570270 @default.
W3087402783 doi "https://doi.org/10.1016/j.electacta.2020.137113" @default.
W3087402783 hasPublicationYear "2020" @default.
W3087402783 type Work @default.
W3087402783 sameAs 3087402783 @default.
W3087402783 citedByCount "11" @default.
W3087402783 countsByYear W30874027832021 @default.
W3087402783 countsByYear W30874027832022 @default.
W3087402783 countsByYear W30874027832023 @default.
W3087402783 crossrefType "journal-article" @default.
W3087402783 hasAuthorship W3087402783A5030059719 @default.
W3087402783 hasAuthorship W3087402783A5035440542 @default.
W3087402783 hasAuthorship W3087402783A5049293174 @default.
W3087402783 hasAuthorship W3087402783A5053882650 @default.
W3087402783 hasAuthorship W3087402783A5067301238 @default.
W3087402783 hasAuthorship W3087402783A5068791597 @default.
W3087402783 hasAuthorship W3087402783A5077701818 @default.
W3087402783 hasAuthorship W3087402783A5080311794 @default.
W3087402783 hasBestOaLocation W30874027831 @default.
W3087402783 hasConcept C114506045 @default.
W3087402783 hasConcept C127413603 @default.
W3087402783 hasConcept C131540310 @default.
W3087402783 hasConcept C135473242 @default.