Your search keyword '"Spectroscopy and Catalysis"' showing total 2 results

1. Nucleophilic versus Electrophilic Reactivity of Bioinspired Superoxido Nickel(II) Complexes

Author

Matthias Driess, Bhawana Pandey, Erik Andris, Teresa Corona, S. Künstner, Chakadola Panda, Jana Roithová, Erik R. Farquhar, Somenath Garai, Kallol Ray, Nils Lindenmaier, Gopalan Rajaraman, and Anirban Chandra

Subjects

Models, Molecular, chemistry.chemical_element, Salt (chemistry), Lithium, 010402 general chemistry, 01 natural sciences, Medicinal chemistry, Catalysis, Nucleophile, Coordination Complexes, Nickel, Superoxides, Spectroscopy and Catalysis, Struktur aktivitats beziehungen, Reactivity (chemistry), chemistry.chemical_classification, 010405 organic chemistry, General Medicine, General Chemistry, 0104 chemical sciences, Oxygen, chemistry, Electrophile, Oxygenases, Quantum Theory, Salts, Oxidoreductases, Ground state, Oxidation-Reduction

Abstract

The formation and detailed spectroscopic characterization of the first biuret-containing monoanionic superoxido-NiII intermediate [LNiO2 ]- as the Li salt [2; L=MeN[C(=O)NAr)2 ; Ar=2,6-iPr2 C6 H3 )] is reported. It results from oxidation of the corresponding [Li(thf)3 ]2 [LNiII Br2 ] complex M with excess H2 O2 in the presence of Et3 N. The [LNiO2 ]- core of 2 shows an unprecedented nucleophilic reactivity in the oxidative deformylation of aldehydes, in stark contrast to the electrophilic character of the previously reported neutral Nacnac-containing superoxido-NiII complex 1, [L'NiO2 ] (L'=CH(CMeNAr)2 ). According to density-functional theory (DFT) calculations, the remarkably different behaviour of 1 versus 2 can be attributed to their different charges and a two-state reactivity, in which a doublet ground state and a nearby spin-polarized doublet excited-state both contribute in 1 but not in 2. The unexpected nucleophilicity of the superoxido-NiII core of 2 suggests that such a reactivity may also play a role in catalytic cycles of Ni-containing oxygenases and oxidases.

Published

2018

2. Tuning the H‐Atom Transfer Reactivity of Iron(IV)‐Oxo Complexes as Probed by Infrared Photodissociation Spectroscopy

Author

Guilherme L. Tripodi, Lawrence Que, Magda M. J. Dekker, and Jana Roithová

Subjects

Tris, Infrared, reactivity screening, iron-oxo, 010402 general chemistry, 01 natural sciences, Catalysis, C−H activation, Adduct, chemistry.chemical_compound, Hydrogen Atom Transfer | Very Important Paper, Spectroscopy and Catalysis, Reactivity (chemistry), Spectroscopy, Research Articles, mass spectrometry, Ligand, 010405 organic chemistry, Photodissociation, General Chemistry, General Medicine, 3. Good health, 0104 chemical sciences, Crystallography, ion spectroscopy, chemistry, Amine gas treating, Research Article

Abstract

Reactivities of non‐heme iron(IV)‐oxo complexes are mostly controlled by the ligands. Complexes with tetradentate ligands such as [(TPA)FeO]2+ (TPA=tris(2‐pyridylmethyl)amine) belong to the most reactive ones. Here, we show a fine‐tuning of the reactivity of [(TPA)FeO]2+ by an additional ligand X (X=CH3CN, CF3SO3 −, ArI, and ArIO; ArI=2‐(tBuSO2)C6H4I) attached in solution and reveal a thus far unknown role of the ArIO oxidant. The HAT reactivity of [(TPA)FeO(X)]+/2+ decreases in the order of X: ArIO > MeCN > ArI ≈ TfO−. Hence, ArIO is not just a mere oxidant of the iron(II) complex, but it can also increase the reactivity of the iron(IV)‐oxo complex as a labile ligand. The detected HAT reactivities of the [(TPA)FeO(X)]+/2+ complexes correlate with the Fe=O and FeO−H stretching vibrations of the reactants and the respective products as determined by infrared photodissociation spectroscopy. Hence, the most reactive [(TPA)FeO(ArIO)]2+ adduct in the series has the weakest Fe=O bond and forms the strongest FeO−H bond in the HAT reaction., The reaction kinetics of H‐atom transfer mediated by iron(IV)oxo complexes with different cis‐ligands can be studied in a modular flow reactor coupled to MS detection. The HAT reactivity correlates with the intrinsic properties of the isolated complexes in the gas phase. A ligand with a larger binding energy forms a more reactive complex for the HAT reactions, has a weaker FeIV=O bond, and forms a stronger FeIIIO−H bond after the HAT reaction.