SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2327604462> ?p ?o ?g. }

Showing items 1 to 100 of ±140 with 100 items per page.

W2327604462 endingPage "3348" @default.
W2327604462 startingPage "3340" @default.
W2327604462 abstract "ConspectusGlobal advances in industrialization are precipitating increasingly rapid consumption of fossil fuel resources and heightened levels of atmospheric CO2. World sustainability requires viable sources of renewable energy and its efficient use. First-principles quantum mechanics (QM) studies can help guide developments in energy technologies by characterizing complex material properties and predicting reaction mechanisms at the atomic scale. QM can provide unbiased, qualitative guidelines for experimentally tailoring materials for energy applications.This Account primarily reviews our recent QM studies of electrode materials for solid oxide fuel cells (SOFCs), a promising technology for clean, efficient power generation. SOFCs presently must operate at very high temperatures to allow transport of oxygen ions and electrons through solid-state electrolytes and electrodes. High temperatures, however, engender slow startup times and accelerate material degradation. SOFC technologies need cathode and anode materials that function well at lower temperatures, which have been realized with mixed ion–electron conductor (MIEC) materials. Unfortunately, the complexity of MIECs has inhibited the rational tailoring of improved SOFC materials. Here, we gather theoretically obtained insights into oxygen ion conductivity in two classes of perovskite-type materials for SOFC applications: the conventional La1–xSrxMO3 family (M = Cr, Mn, Fe, Co) and the new, promising class of Sr2Fe2–xMoxO6 materials. Using density functional theory + U (DFT+U) with U–J values obtained from ab initio theory, we have characterized the accompanying electronic structures for the two processes that govern ionic diffusion in these materials: (i) oxygen vacancy formation and (ii) vacancy-mediated oxygen migration. We show how the corresponding macroscopic oxygen diffusion coefficient can be accurately obtained in terms of microscopic quantities calculated with first-principles QM.We find that the oxygen vacancy formation energy is a robust descriptor for evaluating oxide ion transport properties. We also find it has a direct relationship with (i) the transition metal–oxygen bond strength and (ii) the extent to which electrons left behind by the departing oxygen delocalize onto the oxygen sublattice. Design principles from our QM results may guide further development of perovskite-based MIEC materials for SOFC applications." @default.
W2327604462 created "2016-06-24" @default.
W2327604462 creator A5007577939 @default.
W2327604462 creator A5051770754 @default.
W2327604462 creator A5067720197 @default.
W2327604462 creator A5076334248 @default.
W2327604462 creator A5090200106 @default.
W2327604462 date "2014-06-27" @default.
W2327604462 modified "2023-10-17" @default.
W2327604462 title "Oxygen Transport in Perovskite-Type Solid Oxide Fuel Cell Materials: Insights from Quantum Mechanics" @default.
W2327604462 cites W1680067875 @default.
W2327604462 cites W1919275980 @default.
W2327604462 cites W1937823893 @default.
W2327604462 cites W1966156734 @default.
W2327604462 cites W1970390411 @default.
W2327604462 cites W1975219839 @default.
W2327604462 cites W1975960906 @default.
W2327604462 cites W1979710130 @default.
W2327604462 cites W1981368803 @default.
W2327604462 cites W1982356449 @default.
W2327604462 cites W1998141434 @default.
W2327604462 cites W2006085628 @default.
W2327604462 cites W2006806329 @default.
W2327604462 cites W2010983131 @default.
W2327604462 cites W2015797475 @default.
W2327604462 cites W2030732802 @default.
W2327604462 cites W2032149933 @default.
W2327604462 cites W2033431655 @default.
W2327604462 cites W2034093414 @default.
W2327604462 cites W2035430220 @default.
W2327604462 cites W2046377347 @default.
W2327604462 cites W2047218923 @default.
W2327604462 cites W2048980032 @default.
W2327604462 cites W2061796237 @default.
W2327604462 cites W2067162543 @default.
W2327604462 cites W2067324174 @default.
W2327604462 cites W2077577514 @default.
W2327604462 cites W2083197600 @default.
W2327604462 cites W2083222334 @default.
W2327604462 cites W2090648588 @default.
W2327604462 cites W2110905433 @default.
W2327604462 cites W2117103384 @default.
W2327604462 cites W2122427541 @default.
W2327604462 cites W2132206849 @default.
W2327604462 cites W2152627164 @default.
W2327604462 cites W2155290879 @default.
W2327604462 cites W2167590372 @default.
W2327604462 cites W2169934955 @default.
W2327604462 cites W2230728100 @default.
W2327604462 cites W2312233546 @default.
W2327604462 cites W2314634692 @default.
W2327604462 cites W2335430683 @default.
W2327604462 cites W938464876 @default.
W2327604462 cites W98900031 @default.
W2327604462 cites W177732007 @default.
W2327604462 doi "https://doi.org/10.1021/ar4003174" @default.
W2327604462 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/24972154" @default.
W2327604462 hasPublicationYear "2014" @default.
W2327604462 type Work @default.
W2327604462 sameAs 2327604462 @default.
W2327604462 citedByCount "111" @default.
W2327604462 countsByYear W23276044622014 @default.
W2327604462 countsByYear W23276044622015 @default.
W2327604462 countsByYear W23276044622016 @default.
W2327604462 countsByYear W23276044622017 @default.
W2327604462 countsByYear W23276044622018 @default.
W2327604462 countsByYear W23276044622019 @default.
W2327604462 countsByYear W23276044622020 @default.
W2327604462 countsByYear W23276044622021 @default.
W2327604462 countsByYear W23276044622022 @default.
W2327604462 countsByYear W23276044622023 @default.
W2327604462 crossrefType "journal-article" @default.
W2327604462 hasAuthorship W2327604462A5007577939 @default.
W2327604462 hasAuthorship W2327604462A5051770754 @default.
W2327604462 hasAuthorship W2327604462A5067720197 @default.
W2327604462 hasAuthorship W2327604462A5076334248 @default.
W2327604462 hasAuthorship W2327604462A5090200106 @default.
W2327604462 hasConcept C121332964 @default.
W2327604462 hasConcept C127413603 @default.
W2327604462 hasConcept C147597530 @default.
W2327604462 hasConcept C147789679 @default.
W2327604462 hasConcept C152365726 @default.
W2327604462 hasConcept C155011858 @default.
W2327604462 hasConcept C159467904 @default.
W2327604462 hasConcept C171250308 @default.
W2327604462 hasConcept C17525397 @default.
W2327604462 hasConcept C178790620 @default.
W2327604462 hasConcept C185592680 @default.
W2327604462 hasConcept C191897082 @default.
W2327604462 hasConcept C192562407 @default.
W2327604462 hasConcept C2778456004 @default.
W2327604462 hasConcept C2779851234 @default.
W2327604462 hasConcept C2781442258 @default.
W2327604462 hasConcept C42360764 @default.
W2327604462 hasConcept C61696701 @default.
W2327604462 hasConcept C68801617 @default.
W2327604462 hasConcept C89395315 @default.
W2327604462 hasConceptScore W2327604462C121332964 @default.