SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2149558118> ?p ?o ?g. }

Showing items 1 to 100 of ±163 with 100 items per page.

W2149558118 endingPage "14384" @default.
W2149558118 startingPage "14378" @default.
W2149558118 abstract "Abstract Achieving a harmonious combination of the efficiency of homogeneous catalysts with the reusability of heterogeneous catalysts is a fundamental and challenging problem. Metal nanoparticles in a suitable matrix offer a potential solution. However an ideal design is yet to be realized, because the critical requirements of facile access to the catalyst, its durability, and ease of retrieval and reuse are difficult to reconcile. We report herein a multilayer free‐standing thin‐film catalyst based on silver nanoparticles, generated in situ inside poly(vinyl alcohol) by using a facile protocol, which shows excellent efficiency and extensive reusability in the prototypical reaction, the reduction of 4‐nitrophenol by sodium borohydride. The “dip catalyst” film, which can start/stop the reaction instantaneously by mere insertion/removal, is used 30 times leading to a total turnover number (TON) of ≈3390, which is unprecedented for this reaction. The efficiency of the catalyst is reduced only marginally at the end of these runs, promising further extended usage. The unique advantage of convenient catalyst monitoring is illustrated by the periodic spectroscopic and microscopic examinations of the thin film, which revealed the basis of its durability. The demonstrated potential of metal‐nanoparticle‐embedded polymer thin films, coupled with their versatility and ease of fabrication, promises extensive applications in chemical catalysis." @default.
W2149558118 created "2016-06-24" @default.
W2149558118 creator A5051359400 @default.
W2149558118 creator A5060950898 @default.
W2149558118 date "2010-10-28" @default.
W2149558118 modified "2023-10-18" @default.
W2149558118 title "A Highly Efficient and Extensively Reusable “Dip Catalyst” Based on a Silver-Nanoparticle-Embedded Polymer Thin Film" @default.
W2149558118 cites W1751561108 @default.
W2149558118 cites W1968974677 @default.
W2149558118 cites W1971009182 @default.
W2149558118 cites W1977013938 @default.
W2149558118 cites W1980495221 @default.
W2149558118 cites W1981815028 @default.
W2149558118 cites W1981921119 @default.
W2149558118 cites W1984259165 @default.
W2149558118 cites W1985901190 @default.
W2149558118 cites W1990641755 @default.
W2149558118 cites W1993796825 @default.
W2149558118 cites W1994342755 @default.
W2149558118 cites W2001680508 @default.
W2149558118 cites W2003733465 @default.
W2149558118 cites W2005282932 @default.
W2149558118 cites W2014564471 @default.
W2149558118 cites W2016912547 @default.
W2149558118 cites W2019111250 @default.
W2149558118 cites W2023070137 @default.
W2149558118 cites W2029100203 @default.
W2149558118 cites W2031610403 @default.
W2149558118 cites W2037415684 @default.
W2149558118 cites W2042731950 @default.
W2149558118 cites W2043321751 @default.
W2149558118 cites W2043711979 @default.
W2149558118 cites W2045435474 @default.
W2149558118 cites W2045937569 @default.
W2149558118 cites W2046849974 @default.
W2149558118 cites W2047145687 @default.
W2149558118 cites W2057644785 @default.
W2149558118 cites W2061266901 @default.
W2149558118 cites W2065820181 @default.
W2149558118 cites W2066087901 @default.
W2149558118 cites W2069402155 @default.
W2149558118 cites W2071692111 @default.
W2149558118 cites W2077037861 @default.
W2149558118 cites W2083655921 @default.
W2149558118 cites W2086938216 @default.
W2149558118 cites W2087913605 @default.
W2149558118 cites W2088387192 @default.
W2149558118 cites W2089752047 @default.
W2149558118 cites W2094262202 @default.
W2149558118 cites W2095029154 @default.
W2149558118 cites W2101705789 @default.
W2149558118 cites W2108078936 @default.
W2149558118 cites W2119625859 @default.
W2149558118 cites W2127564328 @default.
W2149558118 cites W2127659738 @default.
W2149558118 cites W2129045563 @default.
W2149558118 cites W2133022989 @default.
W2149558118 cites W2136619721 @default.
W2149558118 cites W2141899092 @default.
W2149558118 cites W2145327472 @default.
W2149558118 cites W2149262099 @default.
W2149558118 cites W2159356334 @default.
W2149558118 cites W2162943094 @default.
W2149558118 cites W2166100441 @default.
W2149558118 cites W2168478591 @default.
W2149558118 cites W2169062903 @default.
W2149558118 cites W2734592329 @default.
W2149558118 cites W2952280321 @default.
W2149558118 cites W4230348298 @default.
W2149558118 cites W4233600756 @default.
W2149558118 doi "https://doi.org/10.1002/chem.201001679" @default.
W2149558118 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/21031369" @default.
W2149558118 hasPublicationYear "2010" @default.
W2149558118 type Work @default.
W2149558118 sameAs 2149558118 @default.
W2149558118 citedByCount "79" @default.
W2149558118 countsByYear W21495581182012 @default.
W2149558118 countsByYear W21495581182013 @default.
W2149558118 countsByYear W21495581182014 @default.
W2149558118 countsByYear W21495581182015 @default.
W2149558118 countsByYear W21495581182016 @default.
W2149558118 countsByYear W21495581182017 @default.
W2149558118 countsByYear W21495581182018 @default.
W2149558118 countsByYear W21495581182019 @default.
W2149558118 countsByYear W21495581182020 @default.
W2149558118 countsByYear W21495581182021 @default.
W2149558118 countsByYear W21495581182022 @default.
W2149558118 countsByYear W21495581182023 @default.
W2149558118 crossrefType "journal-article" @default.
W2149558118 hasAuthorship W2149558118A5051359400 @default.
W2149558118 hasAuthorship W2149558118A5060950898 @default.
W2149558118 hasConcept C104304963 @default.
W2149558118 hasConcept C127413603 @default.
W2149558118 hasConcept C136525101 @default.
W2149558118 hasConcept C137981799 @default.
W2149558118 hasConcept C142724271 @default.
W2149558118 hasConcept C155672457 @default.
W2149558118 hasConcept C159985019 @default.