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W4224283371 endingPage "4762" @default.
W4224283371 startingPage "4747" @default.
W4224283371 abstract "The use of functionalized nanoparticles (NPs) and their aggregation in the presence of a targeted analyte is a well-established molecular detection strategy predicated on harnessing specific molecular interactions to the NP periphery. Molecules able to specifically interact with the functionalized NPs alter the unique optical and electrochemical properties of the NPs as a function of interparticle spacing. While many intermolecular interactions have been successfully exploited in this manner in conjunction with aqueous NP systems, the use of non-aqueous NPs in the same capacity is significantly less explored. A fundamental interaction that has not been previously investigated in NP schemes is halogen bonding (XB). XB is an orthogonal, electrostatic interaction between a region of positive electrostatic potential (δ+) on a halogen atom (i.e., XB donor) and a negative (δ-) Lewis base (XB acceptor) molecule. To couple XB with NP systems, ligands featuring a molecular structure that promotes XB interactions need to be identified, optimized, and synthesized for subsequent attachment to NPs. Herein, density functional theory (DFT) and NMR techniques are used to identify a strong XB-donor moiety (-C6F4I) and a synthetic scheme for a thiolate ligand featuring that functionality is devised and executed with high purity/yield (78%). Ligand-exchange reactions allow functionalization of non-aqueous alkanethiolate-protected gold NPs or monolayer-protected clusters (MPCs) with the XB-donor ligands. Functionalized MPCs (f-MPCs), within both assembled films and in solution, are shown to engage in XB interactions with target XB-acceptor molecules. Molecular recognition events, including induced aggregation of the f-MPCs, are characterized with UV-vis spectroscopy, cyclic voltammetry, TEM imaging, and diffusion-ordered spectroscopy NMR with limits of detection of 50-100 nM for strong XB acceptors. While fundamental exploration of XB interactions is ongoing, this study represents a step toward utilizing XB within molecular detection schemes, an application with implications for supramolecular chemistry, forensic, and environmental chemical sensing." @default.
W4224283371 created "2022-04-26" @default.
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W4224283371 date "2022-04-06" @default.
W4224283371 modified "2023-09-30" @default.
W4224283371 title "Monolayer-Protected Gold Nanoparticles Functionalized with Halogen Bonding Capability─An Avenue for Molecular Detection Schemes" @default.
W4224283371 cites W1113914420 @default.
W4224283371 cites W1548914255 @default.
W4224283371 cites W1667350237 @default.
W4224283371 cites W1964270001 @default.
W4224283371 cites W1968044889 @default.
W4224283371 cites W1978604523 @default.
W4224283371 cites W1981782713 @default.
W4224283371 cites W1985043634 @default.
W4224283371 cites W1987341344 @default.
W4224283371 cites W1989867115 @default.
W4224283371 cites W1992083269 @default.
W4224283371 cites W1992369496 @default.
W4224283371 cites W1993077801 @default.
W4224283371 cites W1999364829 @default.
W4224283371 cites W2000759509 @default.
W4224283371 cites W2001380136 @default.
W4224283371 cites W2008503813 @default.
W4224283371 cites W2011241023 @default.
W4224283371 cites W2014302022 @default.
W4224283371 cites W2017631057 @default.
W4224283371 cites W2018417665 @default.
W4224283371 cites W2019140555 @default.
W4224283371 cites W2021145393 @default.
W4224283371 cites W2027284061 @default.
W4224283371 cites W2032983207 @default.
W4224283371 cites W2033096857 @default.
W4224283371 cites W2047940532 @default.
W4224283371 cites W2053774106 @default.
W4224283371 cites W2056855861 @default.
W4224283371 cites W2061002655 @default.
W4224283371 cites W2061691740 @default.
W4224283371 cites W2069006374 @default.
W4224283371 cites W2070519837 @default.
W4224283371 cites W2071273302 @default.
W4224283371 cites W2077228161 @default.
W4224283371 cites W2078641649 @default.
W4224283371 cites W2086463981 @default.
W4224283371 cites W2095231013 @default.
W4224283371 cites W2114988028 @default.
W4224283371 cites W2115803851 @default.
W4224283371 cites W2120894192 @default.
W4224283371 cites W2148912983 @default.
W4224283371 cites W2149446093 @default.
W4224283371 cites W2150697053 @default.
W4224283371 cites W2265596863 @default.
W4224283371 cites W2270819844 @default.
W4224283371 cites W2280986135 @default.
W4224283371 cites W2316133335 @default.
W4224283371 cites W2323329504 @default.
W4224283371 cites W2325373307 @default.
W4224283371 cites W2325747903 @default.
W4224283371 cites W2326164712 @default.
W4224283371 cites W2329133449 @default.
W4224283371 cites W2333879706 @default.
W4224283371 cites W2431098894 @default.
W4224283371 cites W2504844715 @default.
W4224283371 cites W2520102440 @default.
W4224283371 cites W2618442314 @default.
W4224283371 cites W2751684660 @default.
W4224283371 cites W2766194957 @default.
W4224283371 cites W2783184596 @default.
W4224283371 cites W2804619348 @default.
W4224283371 cites W2810255181 @default.
W4224283371 cites W2810893461 @default.
W4224283371 cites W2882149920 @default.
W4224283371 cites W2885955465 @default.
W4224283371 cites W2895967184 @default.
W4224283371 cites W2898955132 @default.
W4224283371 cites W2912607159 @default.
W4224283371 cites W2917495764 @default.
W4224283371 cites W2979389063 @default.
W4224283371 cites W2994633158 @default.
W4224283371 cites W3130378803 @default.
W4224283371 cites W3154382974 @default.
W4224283371 cites W3190829695 @default.
W4224283371 cites W3205625962 @default.
W4224283371 doi "https://doi.org/10.1021/acs.langmuir.2c00381" @default.
W4224283371 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/35385292" @default.
W4224283371 hasPublicationYear "2022" @default.
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