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W3120751768 startingPage "1136" @default.
W3120751768 abstract "The recent development of liquid cell (scanning) transmission electron microscopy (LC-(S)TEM) has opened the unique possibility of studying the chemical behavior of nanomaterials down to the nanoscale in a liquid environment. Here, we show that the chemically induced etching of three different types of silica-based silica nanoparticles can be reliably studied at the single particle level using LC-(S)TEM with a negligible effect of the electron beam, and we demonstrate this method by successfully monitoring the formation of silica-based heterogeneous yolk–shell nanostructures. By scrutinizing the influence of electron beam irradiation, we show that the cumulative electron dose on the imaging area plays a crucial role in the observed damage and needs to be considered during experimental design. Monte-Carlo simulations of the electron trajectories during LC-(S)TEM experiments allowed us to relate the cumulative electron dose to the deposited energy on the particles, which was found to significantly alter the silica network under imaging conditions of nanoparticles. We used these optimized LC-(S)TEM imaging conditions to systematically characterize the wet etching of silica and metal(oxide)–silica core–shell nanoparticles with cores of gold and iron oxide, which are representative of many other core–silica–shell systems. The LC-(S)TEM method reliably reproduced the etching patterns of Stöber, water-in-oil reverse microemulsion (WORM), and amino acid-catalyzed silica particles that were reported before in the literature. Furthermore, we directly visualized the formation of yolk–shell structures from the wet etching of Au@Stöber silica and Fe3O4@WORM silica core–shell nanospheres." @default.
W3120751768 created "2021-01-18" @default.
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W3120751768 date "2021-01-05" @default.
W3120751768 modified "2023-09-27" @default.
W3120751768 title "In Situ Study of the Wet Chemical Etching of SiO2 and Nanoparticle@SiO2 Core–Shell Nanospheres" @default.
W3120751768 cites W1971637312 @default.
W3120751768 cites W1975663362 @default.
W3120751768 cites W1981476144 @default.
W3120751768 cites W1982186642 @default.
W3120751768 cites W1987522898 @default.
W3120751768 cites W1991307222 @default.
W3120751768 cites W1993202252 @default.
W3120751768 cites W2009224074 @default.
W3120751768 cites W2017463626 @default.
W3120751768 cites W2019541463 @default.
W3120751768 cites W2020532243 @default.
W3120751768 cites W2027072798 @default.
W3120751768 cites W2027404904 @default.
W3120751768 cites W2028811333 @default.
W3120751768 cites W2030659778 @default.
W3120751768 cites W2031004957 @default.
W3120751768 cites W2034294775 @default.
W3120751768 cites W2040521012 @default.
W3120751768 cites W2040725446 @default.
W3120751768 cites W2043735805 @default.
W3120751768 cites W2047898814 @default.
W3120751768 cites W2055009788 @default.
W3120751768 cites W2062989383 @default.
W3120751768 cites W2065021103 @default.
W3120751768 cites W2068161718 @default.
W3120751768 cites W2070257943 @default.
W3120751768 cites W2071794968 @default.
W3120751768 cites W2072018872 @default.
W3120751768 cites W2077563148 @default.
W3120751768 cites W2079995854 @default.
W3120751768 cites W2084273768 @default.
W3120751768 cites W2089124524 @default.
W3120751768 cites W2090763727 @default.
W3120751768 cites W2095055539 @default.
W3120751768 cites W2099049147 @default.
W3120751768 cites W2099966776 @default.
W3120751768 cites W2100334428 @default.
W3120751768 cites W2108137941 @default.
W3120751768 cites W2118969052 @default.
W3120751768 cites W2130861490 @default.
W3120751768 cites W2142755293 @default.
W3120751768 cites W2154448318 @default.
W3120751768 cites W2163643825 @default.
W3120751768 cites W2165412671 @default.
W3120751768 cites W2166523962 @default.
W3120751768 cites W2208532855 @default.
W3120751768 cites W2277921122 @default.
W3120751768 cites W2330656417 @default.
W3120751768 cites W2331238623 @default.
W3120751768 cites W2346030527 @default.
W3120751768 cites W2416006905 @default.
W3120751768 cites W2518509879 @default.
W3120751768 cites W2530665662 @default.
W3120751768 cites W2560590363 @default.
W3120751768 cites W2563986004 @default.
W3120751768 cites W2577983863 @default.
W3120751768 cites W2591713154 @default.
W3120751768 cites W2606166721 @default.
W3120751768 cites W2606903347 @default.
W3120751768 cites W2739122926 @default.
W3120751768 cites W2800818826 @default.
W3120751768 cites W2801148178 @default.
W3120751768 cites W2887155840 @default.
W3120751768 cites W2898340074 @default.
W3120751768 cites W2902298966 @default.
W3120751768 cites W2912325502 @default.
W3120751768 cites W2915183142 @default.
W3120751768 cites W2918537564 @default.
W3120751768 cites W2945044264 @default.
W3120751768 cites W3023217147 @default.
W3120751768 cites W3098391561 @default.
W3120751768 cites W3102469503 @default.
W3120751768 cites W4230164597 @default.
W3120751768 cites W603495185 @default.
W3120751768 doi "https://doi.org/10.1021/acsanm.0c02771" @default.
W3120751768 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/7976607" @default.
W3120751768 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/33763630" @default.
W3120751768 hasPublicationYear "2021" @default.
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