The interaction of the protonated forms of tris(2-aminoethyl amine (tren) with NO3-, SO42-, TsO-, PO43-, P2O74-, and P3O105- was studied by means of potentiometric and microcalorimetric measurements in a 0.10 M NMe4Cl aqueous solution at 298.1 ( 0.1 K, affording stability constants and the relevant energetic terms ΔH° and TΔS° of complexation. Thermodynamic data show that these anion complexation processes are mainly controlled by electrostatic forces, although hydrogen-bond interactions and solvation effects also contribute to complex stability, leading, in some cases, to special ΔH° and TΔS° contributions. The crystal structures of [H3L][NO3]3 and [H3L][TsO]3 evidence a preferred tridentate coordination mode of the triprotonated ligands in the solid state. Accordingly, the H3L3+ receptor binds a single oxygen atom of both NO3 - and TsO- by means of its three protonated fingers, although in the crystal structure of [H3L][TsO]3, one conformer displaying bidentate coordination was also found. Modeling studies performed on the [H3L(NO3)]2+ complex suggested that the tridentate binding mode is the preferred one in aqueous solution, while in the gas phase, a different complex conformation in which the receptor interacts with all three oxygen atoms of NO3- is more stable.
Anion binding by protonated forms of the tripodal ligand tren / C.Bazzicalupi; A.Bencini; A.Bianchi; A.Danesi; C.Giorgi; B.Valtancoli. - In: INORGANIC CHEMISTRY. - ISSN 0020-1669. - STAMPA. - 48:(2009), pp. 2391-2398. [10.1021/ic8013128]
Anion binding by protonated forms of the tripodal ligand tren
BAZZICALUPI, CARLA;BENCINI, ANDREA;BIANCHI, ANTONIO;GIORGI, CLAUDIA;VALTANCOLI, BARBARA
2009
Abstract
The interaction of the protonated forms of tris(2-aminoethyl amine (tren) with NO3-, SO42-, TsO-, PO43-, P2O74-, and P3O105- was studied by means of potentiometric and microcalorimetric measurements in a 0.10 M NMe4Cl aqueous solution at 298.1 ( 0.1 K, affording stability constants and the relevant energetic terms ΔH° and TΔS° of complexation. Thermodynamic data show that these anion complexation processes are mainly controlled by electrostatic forces, although hydrogen-bond interactions and solvation effects also contribute to complex stability, leading, in some cases, to special ΔH° and TΔS° contributions. The crystal structures of [H3L][NO3]3 and [H3L][TsO]3 evidence a preferred tridentate coordination mode of the triprotonated ligands in the solid state. Accordingly, the H3L3+ receptor binds a single oxygen atom of both NO3 - and TsO- by means of its three protonated fingers, although in the crystal structure of [H3L][TsO]3, one conformer displaying bidentate coordination was also found. Modeling studies performed on the [H3L(NO3)]2+ complex suggested that the tridentate binding mode is the preferred one in aqueous solution, while in the gas phase, a different complex conformation in which the receptor interacts with all three oxygen atoms of NO3- is more stable.File | Dimensione | Formato | |
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