Wade A. Neiwert scite author profile

The protonated titanium peroxo complex [Bu(4)N](4)[HPTi(O(2))W(11)O(39)] (1) has been first prepared via interaction of the micro-oxo dimeric heteropolytungstate [Bu(4)N](8)[(PTiW(11)O(39))(2)O] (3) with an excess of 30% aqueous H(2)O(2) in MeCN. Peroxo complex 1 has been characterized by using elemental analysis, UV-vis, IR, resonance Raman (RR), (31)P and (183)W NMR spectroscopy, cyclic voltammetry, and potentiometric titration. The electronic and vibrational spectra of 1 are very similar to those of the well-known unprotonated titanium peroxo complex [Bu(4)N](5)[PTi(O(2))W(11)O(39)] (2), while (31)P and (183)W NMR spectra differ significantly. A compilation of the physicochemical techniques supports a monomeric Keggin type structure of 1 bearing one peroxo ligand attached to Ti(IV) in a eta(2)-coordination mode. The protonation of the titanium peroxo complex results in an increase of the redox potential of the peroxo group, E(1/2) = 1.25 and 0.88 V relative to Ag/AgCl reference electrode for 1 and 2, respectively. In contrast to 2, 1 readily reacts with 2,3,6-trimethylphenol (TMP) at 40 degrees C in MeCN to give 2,2',3,3',5,5'-hexamethyl-4,4'-biphenol (BP) and 2,3,5-trimethyl-p-benzoquinone (TMBQ). The proportion between BP and TMBQ in the reaction products depends on the TMP/1 ratio. When a 2-fold excess of TMP is used, the main reaction product is BP (90%), while using a 2-fold excess of 1 leads to TMBQ (95%). On the basis of the product study, a homolytic oxidation mechanism that implicates the formation of phenoxyl radicals is suggested. The RR deuterium labeling experiments show that the activating proton is most likely localized at a Ti-O-W bridging oxygen rather than at the peroxo group. Theoretical calculations carried out at the DFT level on the protonated and unprotonated titanium peroxo derivatives also propose that the most stable complex is formed preferentially after protonation of the Ti-O-W site; however, both Ti-OH-W and TiOO-H protonated anions could coexist in solution.

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A Late-Transition Metal Oxo Complex: K ₇ Na ₉ [O=Pt ^IV (H ₂ O)L ₂ ], L = [PW ₉ O ₃₄ ] ^9-

Anderson

Neiwert

Kirk

et al. 2004

Science

159

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Terminal mono-oxo complexes of the late transition metal elements have long been considered too unstable to synthesize because of repulsion between the oxygen electrons and the mostly filled metal d orbitals. A platinum(IV)-oxo compound flanked by two polytungstate ligands, K 7 Na 9 [O=Pt(H 2 O)L 2 ], L = [PW 9 O 34 9– ], has now been prepared and isolated at room temperature as air-stable brown crystals. X-ray and neutron diffraction at 30 kelvin revealed a very short [1.720(18) angstrom] Pt–O bond and no evidence of a hydrogen atom at the terminal oxygen, ruling out a better precedented Pt–OH complex. Density functional theory and spectroscopic data account for the stability of the Pt(IV)-oxo unit by electron withdrawal into delocalized orbitals of the polytungstates.

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Wade A. Neiwert

First Isolated Active Titanium Peroxo Complex: Characterization and Theoretical Study

A Late-Transition Metal Oxo Complex: K ₇ Na ₉ [O=Pt ^IV (H ₂ O)L ₂ ], L = [PW ₉ O ₃₄ ] ^9-

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Wade A. Neiwert

First Isolated Active Titanium Peroxo Complex: Characterization and Theoretical Study

A Late-Transition Metal Oxo Complex: K 7 Na 9 [O=Pt IV (H 2 O)L 2 ], L = [PW 9 O 34 ] 9-

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A Late-Transition Metal Oxo Complex: K ₇ Na ₉ [O=Pt ^IV (H ₂ O)L ₂ ], L = [PW ₉ O ₃₄ ] ^9-