Your search keyword '"Tanya K. Todorova"' showing total 5 results

1. Controlling Hydrogen Evolution during Photoreduction of CO

Author

Tanya K, Todorova, Tran Ngoc, Huan, Xia, Wang, Hemlata, Agarwala, and Marc, Fontecave

Abstract

The photochemical reduction of CO

Published

2019

2. Molecular and Electronic Structure of Re2Br4(PMe3)4

Author

Tanya K. Todorova, Frederic Poineau, Roland Lindh, Alfred P. Sattelberger, Lasse Kragh Sørensen, Paul M. Forster, Kenneth R. Czerwinski, Ignacio Fernández Galván, and Erik V. Johnstone

Subjects

010304 chemical physics, Absorption spectroscopy, chemistry.chemical_element, Electronic structure, Rhenium, 010402 general chemistry, Triple bond, 01 natural sciences, Bond order, 0104 chemical sciences, Inorganic Chemistry, Crystallography, chemistry, 0103 physical sciences, Physical and Theoretical Chemistry, Isostructural, Spectroscopy, Monoclinic crystal system

Abstract

The dinuclear rhenium(II) complex Re2Br4(PMe3)4 was prepared from the reduction of [Re2Br8](2-) with (n-Bu4N)BH4 in the presence of PMe3 in propanol. The complex was characterized by single-crystal X-ray diffraction (SCXRD) and UV-visible spectroscopy. It crystallizes in the monoclinic C2/c space group and is isostructural with its molybdenum and technetium analogues. The Re-Re distance (2.2521(3) Å) is slightly longer than the one in Re2Cl4(PMe3)4 (2.247(1) Å). The molecular and electronic structure of Re2X4(PMe3)4 (X = Cl, Br) were studied by multiconfigurational quantum chemical methods. The computed ground-state geometry is in excellent agreement with the experimental structure determined by SCXRD. The calculated total bond order (2.75) is consistent with the presence of an electron-rich triple bond and is similar to the one found for Re2Cl4(PMe3)4. The electronic absorption spectrum of Re2Br4(PMe3)4 was recorded in benzene and shows a series of low-intensity bands in the range 10 000-26 000 cm(-1). The absorption bands were assigned based on calculations of the excitation energies with the multireference wave functions followed by second-order perturbation theory using the CASSCF/CASPT2 method. Calculations predict that the lowest energy band corresponds to the δ* → σ* transition, while the next higher energy bands were attributed to the δ* → π*, δ → σ*, and δ → π* transitions.

Published

2016

3. Octafluorodirhenate(III) Revisited: Solid-State Preparation, Characterization, and Multiconfigurational Quantum Chemical Calculations

Author

Ulrich Abram, Tanya K. Todorova, Alfred P. Sattelberger, Frederic Poineau, Thomas Hartmann, Chien Thang Pham, and Samundeeswari Mariappan Balasekaran

Subjects

010304 chemical physics, Absorption spectroscopy, Infrared, Chemistry, Analytical chemistry, Electronic structure, Fluorine-19 NMR, Ammonium bifluoride, 010402 general chemistry, 01 natural sciences, Bond order, 0104 chemical sciences, Inorganic Chemistry, chemistry.chemical_compound, Yield (chemistry), 0103 physical sciences, Physical chemistry, Physical and Theoretical Chemistry, Spectroscopy

Abstract

A simple method for the high-yield preparation of (NH4)2[Re2F8]·2H2O has been developed that involves the reaction of (n-Bu4N)2[Re2Cl8] with molten ammonium bifluoride (NH4HF2). Using this method, the new salt [NH4]2[Re2F8]·2H2O was prepared in ∼90% yield. The product was characterized in solution by ultraviolet-visible light (UV-vis) and (19)F nuclear magnetic resonance ((19)F NMR) spectroscopies and in the solid-state by elemental analysis, powder X-ray diffraction (XRD), and infrared (IR) spectroscopy. Multiconfigurational CASSCF/CASPT2 quantum chemical calculations were performed to investigate the molecular and electronic structure, as well as the electronic absorption spectrum of the [Re2F8](2-) anion. The metal-metal bonding in the Re2(6+) unit was quantified in terms of effective bond order (EBO) and compared to that of its [Re2Cl8](2-) and [Re2Br8](2-) analogues.

Published

2016

4. Structural, Spectroscopic, and Multiconfigurational Quantum Chemical Investigations of the Electron-Rich Metal−Metal Triple-Bonded Tc2X4(PMe3)4 (X = Cl, Br) Complexes

Author

Tanya K. Todorova, Alfred P. Sattelberger, Frederic Poineau, Paul M. Forster, Kenneth R. Czerwinski, and Laura Gagliardi

Subjects

Chemistry, Trimethylphosphine, Electron, Bond order, Inorganic Chemistry, Crystallography, chemistry.chemical_compound, Computational chemistry, ddc:540, Density functional theory, Physical and Theoretical Chemistry, Isostructural, Cyclic voltammetry, Spectroscopy, Monoclinic crystal system

Abstract

The compounds Tc(2)Cl(4)(PMe(3))(4) and Tc(2)Br(4)(PMe(3))(4) were formed from the reaction between (n-Bu(4)N)(2)Tc(2)X(8) (X = Cl, Br) and trimethylphosphine. The Tc(II) dinuclear species were characterized by single-crystal XRD, UV-visible spectroscopy, and cyclic voltammetry techniques, and the results are compared to those obtained from density functional theory and multiconfigurational (CASSCF/CASPT2) quantum chemical studies. The compound Tc(2)Cl(4)(PMe(3))(4) crystallizes in the monoclinic space group C2/c [a = 17.9995(9) A, b = 9.1821(5) A, c = 17.0090(9) A, beta = 115.4530(10) degrees ] and is isostructural to M(2)Cl(4)(PMe(3))(4) (M = Re, Mo, W) and to Tc(2)Br(4)(PMe(3))(4). The metal-metal distance (2.1318(2) A) is similar to the one found in Tc(2)Br(4)(PMe(3))(4) (2.1316(5) A). The calculated molecular structures of the ground states are in excellent agreement with the structures determined experimentally. Calculations of effective bond orders for Tc(2)X(8)(2-) and Tc(2)X(4)(PMe(3))(4) (X = Cl, Br) indicate stronger pi bonds in the Tc(2)(4+) core than in Tc(2)(6+) core. The electronic spectra were recorded in benzene and show a series of low intensity bands in the range 10 000-26 000 cm(-1). Assignment of the bands as well as computing their excitation energies and intensities were performed at both TD-DFT and CASSCF/CASPT2 levels of theory. Calculations predict that the lowest energy band corresponds to the delta* --sigma* transition, the difference between calculated and experimental values being 228 cm(-1) for X = Cl and 866 cm(-1) for X = Br. The next bands are attributed to delta* --pi*, delta --sigma*, and delta --pi* transitions. The cyclic voltammograms exhibit two reversible waves and indicate that Tc(2)Br(4)(PMe(3))(4) exhibits more positive oxidation potentials than Tc(2)Cl(4)(PMe(3))(4.) This phenomenon is discussed and ascribed to stronger metal (d) to halide (d) back bonding in the bromo complex. Further analysis indicates that Tc(II) dinuclear species containing pi-acidic phosphines are more difficult to oxidize, and a correlation between oxidation potential and phosphine acidity was established.

Published

2010

5. On the Analysis of the Cr−Cr Multiple Bond in Several Classes of Dichromium Compounds

Author

Marcin Brynda, Björn O. Roos, Laura Gagliardi, G. La Macchia, Tanya K. Todorova, Francesco Aquilante, and G. Li Manni

Subjects

Steric effects, Ligand, Stereochemistry, Bond order, Inorganic Chemistry, Bond length, chemistry.chemical_compound, chemistry, ddc:540, Theoretical chemistry, Pi interaction, Physical and Theoretical Chemistry, Bimetallic strip, Quintuple bond

Abstract

Since the discovery of a formal quintuple bond in Ar'CrCrAr' (CrCr = 1.835 angstrom) by Power and co-workers in 2005, many efforts have been dedicated to isolating dichromium species featuring quintuple-bond character. In the present study we investigate the electronic configuration of several, recently synthesized dichromium species with ligands using nitrogen to coordinate the metal centers. The bimetallic bond distances of Power's compound and Cr-2-diazadiene (1) (CrCr = 1.803 angstrom) are compared to those found for Cr-2(mu-eta(2)-ArNC(R)NAr)(2) (2) (CrCr = 1.746 angstrom; R = H, Ar = 2,6-Et2C6H3), Cr-2(mu-eta(2)-(ArNC)-N-Xyl(H)NArXyl)(3) (3) (CrCr = 1.740(reduced)/1.817(neutral) angstrom; Ar-Xyl=2,6-C6H3-(CH3)(2)), Cr-2(mu-eta(2)-TippPyNMes)(2) (4) (CrCr = 1.749 angstrom; TippPyNMes = 6-(2,4,6-triisopropylphenyl)pyridin-2-yl (2,4,6-trimethylphenyl)-amide), and Cr-2(mu-eta(2)-DippNC(NMe2)N-Dipp)(2) (5) (CrCr = 1.729 angstrom, Dipp = 2,6-i-Pr2C6H3). We show that the correlation between the CrCr bond length and the effective bond order (EBO) is strongly affected by the nature of the ligand, as well as by the steric hindrance due to the ligand structure (e.g., the nature of the coordinating nitrogen). A linear correlation between the EBO and CrCr bond distance is established within the same group of ligands. As a result, the CrCr species based on the amidinate, aminopyridinate, and guanidinate ligands have bond patterns similar to the Ar'CrCrAr' compound. Unlike these latter species, the dichromium diazadiene complex is characterized by a different bonding pattern involving Cr-N pi interactions, resulting in a lower bond order associated with the short metal-metal bond distance. In this case the short CrCr distance is most probably the result of the constraints imposed by the diazadiene ligand, implying a Cr2N4 core with a closer CrCr interaction. (Less)

Published

2010