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Experimental and computational studies of selective recognition of Hg2+ by amide linked lower rim 1,3-dibenzimidazole derivative of calix[4]arene: Species characterization in solution and that in the isolated complex, including the delineation of the nanostructures

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Title Experimental and computational studies of selective recognition of Hg2+ by amide linked lower rim 1,3-dibenzimidazole derivative of calix[4]arene: Species characterization in solution and that in the isolated complex, including the delineation of the nanostructures
 
Creator JOSEPH, R
RAMANUJAM, B
ACHARYA, A
KHUTIA, A
RAO, CP
 
Subject transition-metal cations
binding-sites
bearing 2
fluorescent
ion
chemosensor
mercury
sensor
fluoroionophore
behavior
 
Description Amide linked lower rim 1,3-dibenzimidazole derivative of calix[4]arene, L has been shown to be sensitive and selective to Hg2+ in aqueous acetonitrile solution based on fluorescence spectroscopy, and the stoichiometry of the complexed species has been found to be 1:1. The selectivity of L toward Hg2+ has been shown among 11 M2+ ions, viz., Mn2+, Fe2+, CO2+, Ni2+, Cu2+, Zn2+, Cd2+, Hg2+, Ph2+, Ca2+, and Mg2+ studied, including those of the mercury group and none of these ions impede the recognition of Hg2+ by L. Role of the solvent on the recognition of Hg2+ has been demonstrated. The role of calix[4]arene platform and the benzimidazole moieties in the recognition of Hg2+ by L has been delineated upon performing such studies with five different molecules of relevance as reference molecular systems. The binding cores formed by the receptor L and the reference compounds have been established based on the single crystal XRD structures, and the preferential metal ion binding cores have been discussed. The binding, of Hg2+ with L has been further established based on H-1 and C-13 NMR, ESI MS, absorption, and fluorescence lifetime measurements. Some of these techniques have been used to establish the stoichiometry of the species formed. The complex species formed between L and Hg2+ have been isolated and characterized and found to be 1:1 species even in the isolated complex. Whereas transmission electron microscopy (TEM), atomic force microscopy (AFM), and scanning electron microscopy (SEM) provided the nanostructural behavior of L, the TEM and SEM demonstrated that the mercury complex has different characteristics when compared to L. The TEM, SEM, and powder XRD studies revealed that whereas L is crystalline, that of the mercury complex is not, perhaps a reason for not being able to obtain single crystals of the complex. Binding characteristics of Hg2+ toward L have been established based on the DFT computational calculations.
 
Publisher AMER CHEMICAL SOC
 
Date 2011-07-14T02:58:57Z
2011-12-26T12:47:31Z
2011-12-27T05:35:49Z
2011-07-14T02:58:57Z
2011-12-26T12:47:31Z
2011-12-27T05:35:49Z
2008
 
Type Article
 
Identifier JOURNAL OF ORGANIC CHEMISTRY, 73(15), 5745-5758
0022-3263
http://dx.doi.org/10.1021/jo800073g
http://dspace.library.iitb.ac.in/xmlui/handle/10054/3842
http://hdl.handle.net/10054/3842
 
Language en