Tris(3-aminopropyl)amine-based tripodal urea and thiourea receptors, tris([(4-cyanophenyl)amino]propyl)urea (L1) and tris([(4-cyanophenyl)amino]propyl)thiourea (L2), have been synthesized and their anion binding properties have been investigated for halides and oxoanions. As investigated by 1H NMR titrations, each receptor binds an anion with a 1:1 stoichiometry via hydrogen-bonding interactions (NH⋯anion), showing the binding trend in the order of F- > H2PO4- > HCO3- > HSO4- > CH3COO- > SO42- > Cl- > Br- > I in DMSO-d6 . The interactions of the receptors were further studied by 2D NOESY, showing the loss of NOESY contacts of two NH resonances for the complexes of F-, H2PO4-, HCO3-, HSO4- or CH3COO- due to the strong NH⋯anion interactions. The observed higher binding affinity for HSO4- than SO42- is attributed to the proton transfer from HSO4- to the central nitrogen of L1 or L2 which was also supported by the DFT calculations, leading to the secondary acid-base interactions. The thiourea receptor L2 has a general trend to show a higher affinity for an anion as compared to the urea receptor L1 for the corresponding anion in DMSO-d6 . In addition, the compound L2 has been exploited for its extraction properties for fluoride in water using a liquid-liquid extraction technique, and the results indicate that the receptor effectively extracts fluoride from water showing ca. 99% efficiency (based on L2).
Tris(3-aminopropyl)amine-based n class="Chemical">tripodalurea and thiourea receptors, tris([(4-cyanophenyl)amino]propyl)urea (L1) and tris([(4-cyanophenyl)amino]propyl)thiourea (L2), have been synthesized and their anion binding properties have been investigated for halides and oxoanions. As investigated by 1HNMR titrations, each receptor binds an anion with a 1:1 stoichiometry via hydrogen-bonding interactions (NH⋯anion), showing the binding trend in the order ofF- > H2PO4- > HCO3- > HSO4- > CH3COO- > SO42- > Cl- > Br- > IinDMSO-d6 . The interactions of the receptors were further studied by 2D NOESY, showing the loss ofNOESY contacts of two NH resonances for the complexes ofF-, H2PO4-, HCO3-, HSO4- or CH3COO- due to the strong NH⋯anion interactions. The observed higher binding affinity for HSO4- than SO42- is attributed to the proton transfer from HSO4- to the central nitrogen of L1 or L2 which was also supported by the DFT calculations, leading to the secondary acid-base interactions. The thiourea receptor L2 has a general trend to show a higher affinity for an anion as compared to the urea receptor L1 for the corresponding anion inDMSO-d6 . In addition, the compound L2 has been exploited for its extraction properties for fluorideinwater using a liquid-liquid extraction technique, and the results indicate that the receptor effectively extracts fluoridefrom water showing ca. 99% efficiency (based on L2).
Authors: Massimo Boiocchi; Laura Del Boca; David Esteban Gómez; Luigi Fabbrizzi; Maurizio Licchelli; Enrico Monzani Journal: J Am Chem Soc Date: 2004-12-22 Impact factor: 15.419
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Authors: Bobby Portis; Ali Mirchi; Maryam Emami Khansari; Avijit Pramanik; Corey R Johnson; Douglas R Powell; Jerzy Leszczynski; Md Alamgir Hossain Journal: ACS Omega Date: 2017-09-18