SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3039905737> ?p ?o ?g. }

Showing items 1 to 100 of ±173 with 100 items per page.

W3039905737 endingPage "19777" @default.
W3039905737 startingPage "19761" @default.
W3039905737 abstract "The modeling of fuel cells requires the coupling of fluid transport with electro-chemical reactions. There are two approaches commonly used. Firstly, the electrodes can be treated as two planes, where the potential gradient can be considered as being locally one-dimensional. In this case a two dimensional current density distribution is obtained. Secondly, the two electrode layers can be spatially resolved and the protonic and electronic potentials obtained by solving a pair of coupled Poisson equations. The latter approach requires much higher computational resources, because a higher spatial resolution is required and a large set of model parameters is required. On the other hand, much more detailed local information can be obtained by this method. The motivation for this study was to compare the results quantitively with detailed experimental data for a high temperature polymer electrolyte fuel cell with a geometric area of 200 cm2. Both model approaches show very good agreement with measured local current density distributions. The second model is able to provide a deeper insight into the current density variation through the membrane and catalyst layers and reveals points with local extremes. The present results are specific for high temperature polymer electrolyte fuel cells but the conclusions may readily be applied to the modeling of other high temperature fuel cell types." @default.
W3039905737 created "2020-07-10" @default.
W3039905737 creator A5014927795 @default.
W3039905737 creator A5021504578 @default.
W3039905737 creator A5024755690 @default.
W3039905737 creator A5066809952 @default.
W3039905737 creator A5091841971 @default.
W3039905737 date "2020-07-01" @default.
W3039905737 modified "2023-10-12" @default.
W3039905737 title "Polymer electrolyte fuel cell modeling - A comparison of two models with different levels of complexity" @default.
W3039905737 cites W1971022418 @default.
W3039905737 cites W1971860042 @default.
W3039905737 cites W1971880203 @default.
W3039905737 cites W1972508923 @default.
W3039905737 cites W1972694079 @default.
W3039905737 cites W1980196589 @default.
W3039905737 cites W1984799724 @default.
W3039905737 cites W1984851109 @default.
W3039905737 cites W1985192067 @default.
W3039905737 cites W1989586057 @default.
W3039905737 cites W1991352416 @default.
W3039905737 cites W1992289090 @default.
W3039905737 cites W1993337770 @default.
W3039905737 cites W1993540591 @default.
W3039905737 cites W1994844479 @default.
W3039905737 cites W1999061702 @default.
W3039905737 cites W2002013263 @default.
W3039905737 cites W2004529224 @default.
W3039905737 cites W2005415778 @default.
W3039905737 cites W2017903623 @default.
W3039905737 cites W2025174383 @default.
W3039905737 cites W2025378187 @default.
W3039905737 cites W2027648458 @default.
W3039905737 cites W2028268261 @default.
W3039905737 cites W2029599387 @default.
W3039905737 cites W2033330344 @default.
W3039905737 cites W2035262042 @default.
W3039905737 cites W2036149110 @default.
W3039905737 cites W2036882459 @default.
W3039905737 cites W2038285059 @default.
W3039905737 cites W2039211224 @default.
W3039905737 cites W2039236491 @default.
W3039905737 cites W2044307855 @default.
W3039905737 cites W2044903513 @default.
W3039905737 cites W2052652297 @default.
W3039905737 cites W2055124495 @default.
W3039905737 cites W2061716003 @default.
W3039905737 cites W2065015051 @default.
W3039905737 cites W2065239170 @default.
W3039905737 cites W2067126321 @default.
W3039905737 cites W2071097999 @default.
W3039905737 cites W2072245987 @default.
W3039905737 cites W2073595754 @default.
W3039905737 cites W2076896323 @default.
W3039905737 cites W2078395920 @default.
W3039905737 cites W2078453988 @default.
W3039905737 cites W2082340073 @default.
W3039905737 cites W2083590061 @default.
W3039905737 cites W2085426233 @default.
W3039905737 cites W2090730102 @default.
W3039905737 cites W2122399088 @default.
W3039905737 cites W2127250778 @default.
W3039905737 cites W2130649176 @default.
W3039905737 cites W2141770245 @default.
W3039905737 cites W2150124657 @default.
W3039905737 cites W2164781829 @default.
W3039905737 cites W2168575889 @default.
W3039905737 cites W2202013993 @default.
W3039905737 cites W2233622571 @default.
W3039905737 cites W2275838899 @default.
W3039905737 cites W2307832297 @default.
W3039905737 cites W2319026077 @default.
W3039905737 cites W2436518764 @default.
W3039905737 cites W2507962647 @default.
W3039905737 cites W2515657141 @default.
W3039905737 cites W2550534921 @default.
W3039905737 cites W2595622919 @default.
W3039905737 cites W2618359839 @default.
W3039905737 cites W2751073374 @default.
W3039905737 cites W2766380895 @default.
W3039905737 cites W2778241419 @default.
W3039905737 cites W2795893454 @default.
W3039905737 cites W2796145249 @default.
W3039905737 cites W2889727584 @default.
W3039905737 cites W2894977467 @default.
W3039905737 cites W2900961657 @default.
W3039905737 cites W2901820711 @default.
W3039905737 cites W2966438208 @default.
W3039905737 doi "https://doi.org/10.1016/j.ijhydene.2020.05.060" @default.
W3039905737 hasPublicationYear "2020" @default.
W3039905737 type Work @default.
W3039905737 sameAs 3039905737 @default.
W3039905737 citedByCount "11" @default.
W3039905737 countsByYear W30399057372021 @default.
W3039905737 countsByYear W30399057372022 @default.
W3039905737 countsByYear W30399057372023 @default.
W3039905737 crossrefType "journal-article" @default.
W3039905737 hasAuthorship W3039905737A5014927795 @default.