SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4285096985> ?p ?o ?g. }

Showing items 1 to 100 of ±136 with 100 items per page.

W4285096985 endingPage "154238" @default.
W4285096985 startingPage "154238" @default.
W4285096985 abstract "Dissociation of H 2 O on (1 1 1) surfaces of a Pt 0.5 Ni 0.5 bimetal. • Alloying of Pt with Ni has an influence on the electronic structure and the catalytic properties of the bimetals. • Spin-polarised density functional simulations with Hirschfield partitioning (DFT) were used to investigate the electronic properties of five Pt 0.5 Ni 0.5 (1 1 1) surface terminations. • The Mulliken charge analysis revealed that charge transfer occurred between H 2 O, the Pt and Ni atoms, and the environment surrounding the adsorption site. • The 1.5 surface termination, where Ni was the adsorption site, could be a potential electrocatalyst material for the OER or the ORR. One of the biggest challenges for the transition towards renewable energy sources today is the development of affordable platinum (Pt) containing bifunctional bimetals as electrode materials for the oxygen reduction reaction (ORR) and oxygen evolution reaction (OER). Recently, the optimal ratio of a bimetal consisting of Pt and nickel (Ni) was studied. This study included the impact of bimetal mixing on the electronic and magnetic properties of the bimetal. However, the catalytic properties of the bimetal have not been studied and compared to that of the pure metals. In this study, spin-polarized density functional theory calculations were employed to investigate the surface properties of Pt 0.5 Ni 0.5 bimetallic surfaces. Relaxation of the surface terminations showed that the 1.5 (1 1 1) and 0.5 (1 1 1) surface terminations are energetically the most favourable surfaces, while the 2.0 (1 1 1) surface termination is energetically the least favourable surface. However, the 2.0 (1 1 1) surface termination is energetically more favourable than pure Ni. The adsorption of single water (H 2 O) molecule onto various (1 1 1) surface terminations (0.0, 0.5, 1.0, 1.5 and 2.0) of the bimetallic surfaces was investigated. The H 2 O molecule was adsorbed onto the atop site in the most stable orientation, namely parallel to the surface (a flat geometry). The d-band centre revealed that the bonding of the H 2 O molecule on the 0.5 (1 1 1) surface termination is stronger than on the pure Pt surface but weaker than on the pure Ni surface. Bond elongation of the OH bonds and an increase in the HOH bond angle were observed in the H 2 O molecule adsorbed on the 0.5 (1 1 1) surface. The results show that the 1.5 (1 1 1) surface termination, where the water adsorbs to a Ni atom, could potentially be used as an electrocatalyst for the water-splitting reaction. However, experimental data are needed to confirm these results." @default.
W4285096985 created "2022-07-14" @default.
W4285096985 creator A5027347487 @default.
W4285096985 creator A5045195244 @default.
W4285096985 creator A5062821526 @default.
W4285096985 date "2022-11-01" @default.
W4285096985 modified "2023-10-16" @default.
W4285096985 title "Catalytic dissociation of a water molecule on the (1 1 1) surfaces of Pt0.5Ni0.5 bimetal: Density functional theory (DFT) study" @default.
W4285096985 cites W1785657293 @default.
W4285096985 cites W1968545719 @default.
W4285096985 cites W1969638059 @default.
W4285096985 cites W1971113415 @default.
W4285096985 cites W1973807144 @default.
W4285096985 cites W1978526482 @default.
W4285096985 cites W1981368803 @default.
W4285096985 cites W1982153238 @default.
W4285096985 cites W1984048502 @default.
W4285096985 cites W1989715904 @default.
W4285096985 cites W1999872530 @default.
W4285096985 cites W2000723365 @default.
W4285096985 cites W2001872897 @default.
W4285096985 cites W2004056552 @default.
W4285096985 cites W2005477983 @default.
W4285096985 cites W2005859942 @default.
W4285096985 cites W2007707666 @default.
W4285096985 cites W2011256735 @default.
W4285096985 cites W2011985957 @default.
W4285096985 cites W2013215895 @default.
W4285096985 cites W2014936180 @default.
W4285096985 cites W2015124676 @default.
W4285096985 cites W2019291521 @default.
W4285096985 cites W2020007931 @default.
W4285096985 cites W2022604289 @default.
W4285096985 cites W2023307937 @default.
W4285096985 cites W2027604680 @default.
W4285096985 cites W2033487617 @default.
W4285096985 cites W2035034028 @default.
W4285096985 cites W2036113194 @default.
W4285096985 cites W2047657267 @default.
W4285096985 cites W2051857963 @default.
W4285096985 cites W2066613146 @default.
W4285096985 cites W2069988560 @default.
W4285096985 cites W2071955309 @default.
W4285096985 cites W2076303661 @default.
W4285096985 cites W2076605490 @default.
W4285096985 cites W2076968595 @default.
W4285096985 cites W2083152258 @default.
W4285096985 cites W2086791985 @default.
W4285096985 cites W2087585288 @default.
W4285096985 cites W2088192590 @default.
W4285096985 cites W2088942252 @default.
W4285096985 cites W2099157029 @default.
W4285096985 cites W2109664124 @default.
W4285096985 cites W2126488629 @default.
W4285096985 cites W2135864667 @default.
W4285096985 cites W2150234030 @default.
W4285096985 cites W2150892770 @default.
W4285096985 cites W2159752439 @default.
W4285096985 cites W2166244948 @default.
W4285096985 cites W2167383445 @default.
W4285096985 cites W2214296688 @default.
W4285096985 cites W2262975721 @default.
W4285096985 cites W2274258295 @default.
W4285096985 cites W2318817745 @default.
W4285096985 cites W2332386396 @default.
W4285096985 cites W2493419047 @default.
W4285096985 cites W2498517100 @default.
W4285096985 cites W2510136453 @default.
W4285096985 cites W2518696367 @default.
W4285096985 cites W2553305250 @default.
W4285096985 cites W2613955866 @default.
W4285096985 cites W2724626482 @default.
W4285096985 cites W2759879058 @default.
W4285096985 cites W2806166550 @default.
W4285096985 cites W2884224590 @default.
W4285096985 cites W2922915553 @default.
W4285096985 cites W2947082230 @default.
W4285096985 cites W2963478880 @default.
W4285096985 cites W3039119315 @default.
W4285096985 cites W3045472684 @default.
W4285096985 cites W3176829714 @default.
W4285096985 cites W4240271339 @default.
W4285096985 cites W4240399320 @default.
W4285096985 cites W4241456496 @default.
W4285096985 cites W4242541807 @default.
W4285096985 cites W4255947324 @default.
W4285096985 doi "https://doi.org/10.1016/j.apsusc.2022.154238" @default.
W4285096985 hasPublicationYear "2022" @default.
W4285096985 type Work @default.
W4285096985 citedByCount "1" @default.
W4285096985 countsByYear W42850969852023 @default.
W4285096985 crossrefType "journal-article" @default.
W4285096985 hasAuthorship W4285096985A5027347487 @default.
W4285096985 hasAuthorship W4285096985A5045195244 @default.
W4285096985 hasAuthorship W4285096985A5062821526 @default.
W4285096985 hasConcept C102931765 @default.
W4285096985 hasConcept C147597530 @default.
W4285096985 hasConcept C147789679 @default.