SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2904230537> ?p ?o ?g. }

Showing items 1 to 100 of ±158 with 100 items per page.

W2904230537 endingPage "715" @default.
W2904230537 startingPage "701" @default.
W2904230537 abstract "We present evidence from kinetic studies and electronic structure calculations that monoclinic ZrO2 and HfO2 can catalyze Diels–Alder [4 + 2] cycloaddition between furan and methyl acrylate. The two oxides present the same apparent activation energies, in the range of 11.5 kcal/mol, but HfO2 seems intrinsically more active. We use density functional theory (DFT) calculations to investigate catalytic pathways and the influence of surface hydration on activity. Partially hydroxylated surfaces are more reactive than the dehydrated or completely hydroxylated surfaces on account of a synergy between Lewis acidic metal centers and surface hydroxyl groups that lowers the LUMO of surface-bound methyl acrylate. We argue that surface hydroxyl groups present a polar environment which, via hydrogen bonding, are solely responsible for the rate acceleration on completely hydroxylated surfaces without necessarily proton transfer. The Lewis metal centers of completely dehydrated surfaces are marginally effective active sites. Upon comparison with γ-Al2O3, which has been reported to catalyze the Diels–Alder of cyclopentadiene with methyl acrylate, we argue that without compromising catalytic efficiency, ZrO2 and HfO2 present the advantage of selective catalysis without need for surface activation or a controlled environment." @default.
W2904230537 created "2018-12-22" @default.
W2904230537 creator A5023183762 @default.
W2904230537 creator A5035446385 @default.
W2904230537 creator A5039313369 @default.
W2904230537 creator A5041001532 @default.
W2904230537 creator A5043069772 @default.
W2904230537 creator A5061694141 @default.
W2904230537 date "2018-12-10" @default.
W2904230537 modified "2023-09-27" @default.
W2904230537 title "Lewis Acid Site and Hydrogen-Bond-Mediated Polarization Synergy in the Catalysis of Diels–Alder Cycloaddition by Band-Gap Transition-Metal Oxides" @default.
W2904230537 cites W1846592770 @default.
W2904230537 cites W1964090131 @default.
W2904230537 cites W1967853451 @default.
W2904230537 cites W1970127494 @default.
W2904230537 cites W1979544533 @default.
W2904230537 cites W1996214740 @default.
W2904230537 cites W1996400924 @default.
W2904230537 cites W1998010646 @default.
W2904230537 cites W2000059078 @default.
W2904230537 cites W2000935529 @default.
W2904230537 cites W2004751437 @default.
W2904230537 cites W2005879789 @default.
W2904230537 cites W2007395042 @default.
W2904230537 cites W2007849230 @default.
W2904230537 cites W2008844584 @default.
W2904230537 cites W2009489922 @default.
W2904230537 cites W2011241123 @default.
W2904230537 cites W2018876915 @default.
W2904230537 cites W2019525883 @default.
W2904230537 cites W2027515659 @default.
W2904230537 cites W2031430816 @default.
W2904230537 cites W2036113194 @default.
W2904230537 cites W2037570317 @default.
W2904230537 cites W2037661249 @default.
W2904230537 cites W2038071232 @default.
W2904230537 cites W2039632336 @default.
W2904230537 cites W2044334619 @default.
W2904230537 cites W2045280638 @default.
W2904230537 cites W2047042008 @default.
W2904230537 cites W2047937197 @default.
W2904230537 cites W2051469879 @default.
W2904230537 cites W2060161221 @default.
W2904230537 cites W2065382771 @default.
W2904230537 cites W2065517642 @default.
W2904230537 cites W2066455016 @default.
W2904230537 cites W2069574515 @default.
W2904230537 cites W2071592915 @default.
W2904230537 cites W2075240025 @default.
W2904230537 cites W2076128582 @default.
W2904230537 cites W2079105963 @default.
W2904230537 cites W2079795679 @default.
W2904230537 cites W2087698390 @default.
W2904230537 cites W2089220876 @default.
W2904230537 cites W2091219582 @default.
W2904230537 cites W2092157292 @default.
W2904230537 cites W2095024313 @default.
W2904230537 cites W2096747776 @default.
W2904230537 cites W2101958915 @default.
W2904230537 cites W2102600409 @default.
W2904230537 cites W2108806320 @default.
W2904230537 cites W2119539213 @default.
W2904230537 cites W2122427541 @default.
W2904230537 cites W2150687058 @default.
W2904230537 cites W2157855637 @default.
W2904230537 cites W2167694012 @default.
W2904230537 cites W2168897064 @default.
W2904230537 cites W2190924194 @default.
W2904230537 cites W2205939970 @default.
W2904230537 cites W2254657057 @default.
W2904230537 cites W2317183013 @default.
W2904230537 cites W2320164150 @default.
W2904230537 cites W2324000401 @default.
W2904230537 cites W2326602004 @default.
W2904230537 cites W2328865417 @default.
W2904230537 cites W2332824798 @default.
W2904230537 cites W2430127522 @default.
W2904230537 cites W2557211021 @default.
W2904230537 cites W2588025836 @default.
W2904230537 cites W2594437520 @default.
W2904230537 cites W2618334140 @default.
W2904230537 cites W2769166533 @default.
W2904230537 cites W2951131805 @default.
W2904230537 doi "https://doi.org/10.1021/acscatal.8b03664" @default.
W2904230537 hasPublicationYear "2018" @default.
W2904230537 type Work @default.
W2904230537 sameAs 2904230537 @default.
W2904230537 citedByCount "14" @default.
W2904230537 countsByYear W29042305372019 @default.
W2904230537 countsByYear W29042305372020 @default.
W2904230537 countsByYear W29042305372021 @default.
W2904230537 countsByYear W29042305372022 @default.
W2904230537 countsByYear W29042305372023 @default.
W2904230537 crossrefType "journal-article" @default.
W2904230537 hasAuthorship W2904230537A5023183762 @default.
W2904230537 hasAuthorship W2904230537A5035446385 @default.
W2904230537 hasAuthorship W2904230537A5039313369 @default.
W2904230537 hasAuthorship W2904230537A5041001532 @default.