SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2327800498> ?p ?o ?g. }

Showing items 1 to 100 of ±165 with 100 items per page.

W2327800498 endingPage "1331" @default.
W2327800498 startingPage "1318" @default.
W2327800498 abstract "There is a specific need for nanoporous monolithic pyrophoric metals as energetic materials and catalysts. Adapting modern-day blast furnace methodology, namely, direct reduction of highly porous iron oxide aerogels with H2 or CO, yielded coarse powders. Turning to smelting reduction, we used the acid environment of gelling [Fe(H2O)6]3+ sols to catalyze co-gelation of a second, extremely sturdy, carbonizable in high yield polybenzoxazine (PBO) network that plays the dual role of a reactive template. Formation of two independent gel networks was confirmed with rheology/dynamic mechanical analysis performed in tandem with the same sol and its gel, and results were correlated with data from microscopy (SEM, STEM) and small-angle X-ray scattering (SAXS) for the elucidation of the exact topological association of the two components. By probing the chemical interaction of the two networks with infrared, Mössbauer, XRD, and CHN analysis, we found out that iron(III) oxide undergoes pre-reduction to Fe3O4 and participates in the oxidation of PBO, which is a prerequisite for robust carbons suitable as structure-directing templates. Subsequently, interconnected submicrometer-size Fe3O4 nanoparticles undergo annealing at more than 800 °C below the melting point of the bulk oxide and are reduced to iron(0) at 800 °C, presumably via a solid (C)/liquid (Fe3O4) process. Carbothermal reduction, oxidative removal of residual carbon (air), and re-reduction (H2) of α-Fe2O3 formed in the previous step were all carried out as a single process by switching gases. The resulting pure iron(0) monoliths had a density of 0.54 ± 0.07 g cm–3 and were 93% porous. Infiltration with LiClO4 and ignition led to a new type of explosive behavior due to rapid heating and expansion of gases filling nanoporous space; annealing at 1200 °C reduced porosity to 66%, and those materials behaved as thermites. Ignition in a bomb calorimeter released 59 ± 9 kcal mol–1 of iron(0) reacted and is associated with oxidation to FeO (theoretical, 66.64 kcal mol–1)." @default.
W2327800498 created "2016-06-24" @default.
W2327800498 creator A5024575846 @default.
W2327800498 creator A5049655899 @default.
W2327800498 creator A5056592229 @default.
W2327800498 creator A5079075280 @default.
W2327800498 creator A5083176634 @default.
W2327800498 creator A5085816001 @default.
W2327800498 date "2014-01-16" @default.
W2327800498 modified "2023-10-04" @default.
W2327800498 title "Polybenzoxazine Aerogels. 2. Interpenetrating Networks with Iron Oxide and the Carbothermal Synthesis of Highly Porous Monolithic Pure Iron(0) Aerogels as Energetic Materials" @default.
W2327800498 cites W107100380 @default.
W2327800498 cites W1569308213 @default.
W2327800498 cites W172550877 @default.
W2327800498 cites W1964393799 @default.
W2327800498 cites W1966294428 @default.
W2327800498 cites W1969610154 @default.
W2327800498 cites W1970544399 @default.
W2327800498 cites W1970728984 @default.
W2327800498 cites W1973514754 @default.
W2327800498 cites W1982920275 @default.
W2327800498 cites W1984588770 @default.
W2327800498 cites W1985633674 @default.
W2327800498 cites W1988176361 @default.
W2327800498 cites W1999028041 @default.
W2327800498 cites W1999094369 @default.
W2327800498 cites W1999493003 @default.
W2327800498 cites W2002666067 @default.
W2327800498 cites W2005112566 @default.
W2327800498 cites W2005395502 @default.
W2327800498 cites W2005682134 @default.
W2327800498 cites W2011215117 @default.
W2327800498 cites W2011512447 @default.
W2327800498 cites W2011789564 @default.
W2327800498 cites W2013277537 @default.
W2327800498 cites W2018205372 @default.
W2327800498 cites W2018434675 @default.
W2327800498 cites W2019346312 @default.
W2327800498 cites W2020256255 @default.
W2327800498 cites W2027066878 @default.
W2327800498 cites W2027630847 @default.
W2327800498 cites W2033533848 @default.
W2327800498 cites W2037255761 @default.
W2327800498 cites W2038135143 @default.
W2327800498 cites W2038232512 @default.
W2327800498 cites W2040484994 @default.
W2327800498 cites W2042554202 @default.
W2327800498 cites W2043121446 @default.
W2327800498 cites W2045420873 @default.
W2327800498 cites W2048953780 @default.
W2327800498 cites W2049270929 @default.
W2327800498 cites W2053036337 @default.
W2327800498 cites W2053494306 @default.
W2327800498 cites W2058169530 @default.
W2327800498 cites W2059152832 @default.
W2327800498 cites W2059384558 @default.
W2327800498 cites W2063192186 @default.
W2327800498 cites W2069160034 @default.
W2327800498 cites W2079779108 @default.
W2327800498 cites W2084904473 @default.
W2327800498 cites W2085093561 @default.
W2327800498 cites W2088320987 @default.
W2327800498 cites W2088713963 @default.
W2327800498 cites W2091907165 @default.
W2327800498 cites W2093596943 @default.
W2327800498 cites W2097674624 @default.
W2327800498 cites W2099113566 @default.
W2327800498 cites W2105418804 @default.
W2327800498 cites W2110117927 @default.
W2327800498 cites W2111398167 @default.
W2327800498 cites W2117851129 @default.
W2327800498 cites W2120167381 @default.
W2327800498 cites W2124775711 @default.
W2327800498 cites W2128186434 @default.
W2327800498 cites W2130910617 @default.
W2327800498 cites W2133337717 @default.
W2327800498 cites W2140551148 @default.
W2327800498 cites W2149091456 @default.
W2327800498 cites W2158190465 @default.
W2327800498 cites W2165685541 @default.
W2327800498 cites W2316729059 @default.
W2327800498 cites W4231960227 @default.
W2327800498 doi "https://doi.org/10.1021/cm403484e" @default.
W2327800498 hasPublicationYear "2014" @default.
W2327800498 type Work @default.
W2327800498 sameAs 2327800498 @default.
W2327800498 citedByCount "66" @default.
W2327800498 countsByYear W23278004982014 @default.
W2327800498 countsByYear W23278004982015 @default.
W2327800498 countsByYear W23278004982016 @default.
W2327800498 countsByYear W23278004982017 @default.
W2327800498 countsByYear W23278004982018 @default.
W2327800498 countsByYear W23278004982019 @default.
W2327800498 countsByYear W23278004982020 @default.
W2327800498 countsByYear W23278004982021 @default.
W2327800498 countsByYear W23278004982022 @default.
W2327800498 countsByYear W23278004982023 @default.
W2327800498 crossrefType "journal-article" @default.