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Start Over Author "Karsten, Meyer" Journal angewandte chemie (international ed. in english)
21 results on '"Karsten, Meyer"'

1. A Pair of Cobalt(III/IV) Terminal Imido Complexes

Author

Weiqing Mao, Dominik Fehn, Dominik Munz, Andreas Scheurer, Frank W. Heinemann, and Karsten Meyer

Subjects
Tertiary amine, Nitrene, chemistry.chemical_element, 010402 general chemistry, 01 natural sciences, Catalysis, law.invention, chemistry.chemical_compound, Negative hyperconjugation, law, Molecule, Moiety, N-heterocyclic carbenes, Methylene, Electron paramagnetic resonance, Research Articles, Cobalt Complexes | Very Important Paper, 010405 organic chemistry, General Medicine, General Chemistry, cobalt, 0104 chemical sciences, terminal imides, Crystallography, chemistry, density functional theory calculations, Cobalt, Research Article, EPR spectroscopy
Abstract

The reaction of the cobalt(I) complex [(TIMMNmes)CoI](BPh4) (2) (TIMMNmes=tris‐[2‐(3‐mesitylimidazolin‐2‐ylidene)methyl]amine) with 1‐adamantylazide yields the cobalt(III) imido complex [(TIMMNmes)CoIII(NAd)](BPh4) (3) with concomitant release of dinitrogen. The N‐anchor in diamagnetic 3 features an unusual, planar tertiary amine, which results from repulsive electrostatic interaction with the filled d(z2)‐orbital of the cobalt ion and negative hyperconjugation with the neighboring methylene groups. One‐electron oxidation of 3 with [FeCp2](OTf) provides access to the rare, high‐valent cobalt(IV) imido complex [(TIMMNmes)CoIV(NAd)](OTf)2 (4). Despite a half‐life of less than 1 h at room temperature, 4 could be isolated at low temperatures in analytically pure form. Single‐crystal X‐ray diffractometry and EPR spectroscopy corroborate the molecular structure and the d5 low‐spin, S=1/2 , electron configuration. A computational analysis of 4 suggests high covalency within the CoIV=NAd bond with non‐negligible spin density located at the imido moiety, which translates into substantial triplet nitrene character., Straightforward access to a cobalt(IV) terminal imido complex was provided by one‐electron oxidation of a cobalt(III) terminal imido precursor. The cobalt(IV) monoimido complex could be isolated at low temperatures in analytically pure form. Single‐crystal X‐ray diffractometry and EPR spectroscopy corroborate the molecular structure and the d5 low‐spin, S=1/2 , electron configuration.

Published
2021

2. Cobalt Diazo‐Compounds: From Nitrilimide to Isocyanoamide via a Diazomethanediide Fleeting Intermediate

Author

Sadig Aghazada, Dominik Fehn, Frank W. Heinemann, Dominik Munz, and Karsten Meyer

Subjects
bond activation, 010405 organic chemistry, Communication, diazo compounds, General Chemistry, 010402 general chemistry, nitrilimines, 01 natural sciences, cobalt, Catalysis, Communications, 3. Good health, 0104 chemical sciences, Coordination Chemistry, density functional theory
Abstract

Lithium trimethylsilyldiazomethanide and a cobalt (II) precursor with an N‐anchored tris‐NHC (TIMENmes) ligand provide access to the cobalt nitrilimide 1. Complex 1 was structurally characterized by single‐crystal X‐ray diffractometry (SC‐XRD) and its electronic structure was examined in detail, including EPR spectroscopy, SQUID magnetometry and computational analyses. The desilylation of the C‐(trimethylsilyl)nitrilimide reveals a transient complex with an elusive diazomethanediide ligand, which substitutes one of the mesitylene rings of the ancillary ligand through C−N bond cleavage. This transformation results in the cyclometalated cobalt(II) complex 2, featuring a rare isocyanoamido‐κ‐C ligand., Trimethylsilylium abstraction from a cobalt nitrilimide complex generates a transient cobalt diazomethanediide complex, which forms a terminal isocyanoamido ligand through a radical de‐arylation.

Published
2021

4. Bis(imidazolium)-1,3-diphosphete-diide: A Building Block for FeC

Author

Moritz Theodor, Scharnhölz, Peter, Coburger, Lisa, Gravogl, Daniel, Klose, Juan José, Gamboa-Carballo, Grégoire, Le Corre, Jonas, Bösken, Clara, Schweinzer, Debora, Thöny, Zhongshu, Li, Karsten, Meyer, and Hansjörg, Grützmacher

Abstract

Reaction of the 6π-electron aromatic four-membered heterocycle (IPr)

Published
2022

5. Synthesis of a Nitrogenase P

Author

Golam, Moula, Ayaka, Nagasaki, Tsuyoshi, Matsumoto, Matthias E, Miehlich, Karsten, Meyer, Roger E, Cramer, and Kazuyuki, Tatsumi

Subjects
Models, Molecular, Iron, Nitrogenase, Molecular Conformation, Chemistry Techniques, Synthetic, Ligands, Ferric Compounds, Sulfur
Abstract

Constructing synthetic models of the nitrogenase P

Published
2021

6. The Influence of β‐diiminato Ligands on As4 Activation by Cobalt Complexes

Author

Gábor Balázs, Christian Graßl, Manfred Scheer, Fabian Spitzer, Martin Keilwerth, and Karsten Meyer

Subjects
Steric effects, substituent effects, 010405 organic chemistry, Communication, small-molecule activation, chemistry.chemical_element, General Chemistry, Thermal treatment, 010402 general chemistry, 01 natural sciences, Catalysis, Communications, 0104 chemical sciences, β-diiminato ligand, Crystallography, Octahedron, chemistry, Yield (chemistry), Proton NMR, paramagnetic compounds, Reactivity (chemistry), yellow arsenic, Spectroscopy, Cobalt, Arsene Ligands
Abstract

In a systematic study of the activation of As-4, three [LCo(tol)] (L=beta-diiminato) complexes have revealed different steric and electronic influences. 2,6-Diisopropylphenyl (Dipp) and 2,6-dimethylphenyl (dmp) flanking groups were used, one of the ligands with H backbone substituents (beta-dialdiminate L-0) and two with Me substituents (beta-diketiminates L-3 and L-1). In the reaction with As-4, different dinuclear products [(LCo)(2)As-4] (LM=L-0 (1), L-1 (2), L-3 (3)) were isolated, with all showing differently shaped [Co2As4] cores in the solid state: octahedral in 1, prismatic in 2, and asterane-like in 3. Thermal treatment of 3 leads to the abstraction of one arsenic atom to yield [((LCo)-Co-3)(2)As-3] (4). All products were comprehensively characterized by single-crystal X-ray diffraction, FD-MS, and (HNMR)-H-1 spectroscopy. A rational explanation for the different reactivity is also proposed and DFT calculations shed light on the nature of the highly flexible [Co2As4] cores.

Published
2018

7. Cyaarside (CAs

Author

Christopher J, Hoerger, Frank W, Heinemann, Elisa, Louyriac, Massimo, Rigo, Laurent, Maron, Hansjörg, Grützmacher, Matthias, Driess, and Karsten, Meyer

Abstract

Reaction of the trivalent uranium complex [((

Published
2018

8. Synthesis of an All-Ferric Cuboidal Iron-Sulfur Cluster [Fe

Author

Golam, Moula, Tsuyoshi, Matsumoto, Matthias E, Miehlich, Karsten, Meyer, and Kazuyuki, Tatsumi

Abstract

An unprecedented, super oxidized all-ferric iron-sulfur cubanoid cluster with all terminal thiolates, Fe

Published
2018

10. Rearrangement of a P

Author

Julian, Müller, Sebastian, Heinl, Christoph, Schwarzmaier, Gábor, Balázs, Martin, Keilwerth, Karsten, Meyer, and Manfred, Scheer

Abstract

The versatile coordination behavior of the P

Published
2017

11. A Stable Crystalline Triarylphosphine Oxide Radical Anion

Author

Tobias A. Schaub, Karsten Meyer, Frank Hampel, Dominik P. Halter, Eva M. Zolnhofer, Tatyana E. Shubina, and Milan Kivala

Subjects
Steric effects, Phosphine oxide, 010405 organic chemistry, Chemistry, Oxide, General Chemistry, 010402 general chemistry, Photochemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, Ion, chemistry.chemical_compound, Polymer chemistry, Moiety, Electronic properties
Abstract

Triarylphosphine oxides (Ar3 P=O) are being intensely studied as electron-accepting (n-type) materials. Despite the widespread application of these compounds as electron conductors, experimental data regarding the structural and electronic properties of their negatively charged states remain scarce owing to their propensity for follow-up chemistry. Herein, a carefully designed triarylphosphine oxide scaffold is disclosed that comprises sterically demanding spirofluorenyl moieties to shield the central phosphoryl (P=O) moiety. This compound undergoes chemical one-electron reduction to afford an exceptionally stable radical anion, which was isolated and characterized by X-ray crystallography for the very first time. The experimental data, corroborated by computational studies, shall allow for the construction of phosphine oxide materials with enhanced stability.

Published
2016

12. Biomimetic [2Fe-2S] clusters with extensively delocalized mixed-valence iron centers

Author

Matthias Driess, Mario Adelhardt, Karsten Meyer, Burgert Blom, Shenglai Yao, Martin Kaupp, Stefan Mebs, Florian Meier, Robert Rudolph, Jörg Sutter, Michael Haumann, and Nils Lindenmaier

Subjects
Iron-Sulfur Proteins, Models, Molecular, X-ray absorption spectroscopy, Valence (chemistry), Molecular Structure, Chemistry, Coordination polymer, Potassium, Inorganic chemistry, chemistry.chemical_element, General Chemistry, Catalysis, chemistry.chemical_compound, Crystallography, Delocalized electron, Biomimetic Materials, Mössbauer spectroscopy, Cluster (physics), Molecule, Quantum Theory, Iron Compounds
Abstract

A complete series of biomimetic [2Fe-2S] clusters, [(L(Dep) Fe)2 (μ-S)2 ] (3, L(Dep) =CH[CMeN(2,6-Et2 C6 H3 )]2 ), [(L(Dep) Fe)2 (μ-S)2 K] (4), [(L(Dep) Fe)2 (μ-S)2 ][Bu4 N] (5, Bu=n-butyl), and [(L(Dep) Fe)2 (μ-S)2 K2 ] (6), could be synthesized and characterized. The all-ferric [2Fe-2S] cluster 3 is readily accessible through the reaction of [(L(Dep) Fe)2 (μ-H)2 ] (2) with elemental sulfur. The chemical reduction of 3 with one molar equivalent of elemental potassium affords the contact ion pair K(+) [2Fe-2S](-) (4) as a one-dimensional coordination polymer, which in turn reacts with [Bu4 N]Cl to afford the separate ion pair [Bu4 N](+) [2Fe-2S](-) (5). Further reduction of 4 with potassium furnishes the super-reduced all-ferrous [2Fe-2S] cluster 6. Remarkably, complexes 4 and 5 are [2Fe-2S] clusters with extensively delocalized Fe(2+) Fe(3+) pairs as evidenced by (57) Fe Mossbauer, X-ray absorption and emission spectroscopy (XAS, XES) and in accordance with DFT calculations.

Published
2015

13. Stable Co-Catalyst-Free Photocatalytic H2 Evolution From Oxidized Titanium Nitride Nanopowders

Author

Ning Liu, Xuemei Zhou, Nhat Truong Nguyen, Patrik Schmuki, Eva M. Zolnhofer, and Karsten Meyer

Subjects
Anatase, Condensed Matter - Materials Science, Materials science, chemistry.chemical_element, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, General Chemistry, General Medicine, engineering.material, Titanium nitride, Catalysis, chemistry.chemical_compound, chemistry, Chemical engineering, Rutile, Phase (matter), Photocatalysis, engineering, Noble metal, Tin
Abstract

In the present work, a simple strategy is used to thermally oxidize TiN nanopowder (ca. 20 nm) to an anatase phase of a TiO2:Ti3+:N compound. In contrast to the rutile phase of such a compound this photocatalyst provides photocatalytic activity for hydrogen evolution under AM1.5 conditions - this without the use of any noble metal co-catalyst. Moreover the photocatalyst is active and stable over extended periods of time (tested for 4 months). Importantly, to achieve successful conversion to the active anatase polymorph, sufficiently small starting particles of TiN are needed. The key factor for catalysis is the stabilization of the co-catalytically active Ti3+ species against oxidation by nitrogen present in the starting material.

Published
2015

14. Low-valent iron(i) amido olefin complexes as promotors for dehydrogenation reactions

Author

Hansjörg Grützmacher, Jörg Sutter, Mario Adelhardt, Karsten Meyer, Crispin Lichtenberg, Bas de Bruin, Liliana Viciu, and Homogeneous and Supramolecular Catalysis (HIMS, FNWI)

Subjects
Olefin fiber, Silanes, Molecular Structure, General Chemistry, Alkenes, Condensation reaction, Medicinal chemistry, Amides, Catalysis, chemistry.chemical_compound, chemistry, Organic chemistry, Dehydrogenation, Azide, Hydrogenation, Bimetallic strip, Stoichiometry, Iron Compounds, Ethers
Abstract

FeI compounds including hydrogenases show remarkable properties and reactivities. Several iron(I) complexes have been established in stoichiometric reactions as model compounds for N2 or CO2 activation. The development of well‐defined iron(I) complexes for catalytic transformations remains a challenge. The few examples include cross‐coupling reactions, hydrogenations of terminal olefins, and azide functionalizations. Here the syntheses and properties of bimetallic complexes [MFeI(trop2dae)(solv)] (M=Na, solv=3 thf; M=Li, solv=2 Et2O; trop=5H ‐dibenzo[a,d]cyclo‐hepten‐5‐yl, dae=(N‐CH2‐CH2‐N) with a d7 Fe low‐spin valence‐electron configuration are reported. Both compounds promote the dehydrogenation of N ,N ‐dimethylaminoborane, and the former is a precatalyst for the dehydrogenative alcoholysis of silanes. No indications for heterogeneous catalyses were found. High activities and complete conversions were observed particularly with [NaFeI(trop2dae)(thf)3].

Published
2014

15. A cis-divacant octahedral and mononuclear iron(IV) imide

Author

Skye Fortier, Patrick J. Carroll, Kenneth G. Caulton, Daniel J. Mindiola, Marat M. Khusniyarov, Keith Searles, Jörg Sutter, and Karsten Meyer

Subjects
Molecular Structure, Ligand, Stereochemistry, Stereoisomerism, General Medicine, General Chemistry, Imides, Medicinal chemistry, Redox, Catalysis, Paramagnetism, chemistry.chemical_compound, chemistry, Octahedron, Octahedral molecular geometry, Pyridine, Mössbauer spectroscopy, Quantum Theory, Imide, Iron Compounds
Abstract

A rare, low-spin Fe(IV) imide complex [(pyrr2py)Fe=NAd] (pyrr2 py(2-) = bis(pyrrolyl)pyridine; Ad = 1-adamantyl) confined to a cis-divacant octahedral geometry, was prepared by reduction of N3Ad by the Fe(II) precursor [(pyrr2py)Fe(OEt2)]. The imide complex is low-spin with temperature-independent paramagnetism. In comparison to an authentic Fe(III) complex, such as [(pyrr2py)FeCl], the pyrr2py(2-) ligand is virtually redox innocent.

Published
2014

16. Synthesis and characterization of a uranium(II) monoarene complex supported by δ backbonding

Author

Henry S. La Pierre, Wolfgang Hieringer, Frank W. Heinemann, Andreas Scheurer, and Karsten Meyer

Subjects
Models, Molecular, Absorption spectroscopy, Magnetism, Potassium, chemistry.chemical_element, General Chemistry, Electronic structure, General Medicine, Uranium, Catalysis, law.invention, Crystallography, chemistry, law, Coordination Complexes, Quantum Theory, Electron configuration, Electron paramagnetic resonance, Pi backbonding
Abstract

The low-temperature (-35 °C) reduction of the trivalent uranium monoarene complex [{((Ad,Me) ArO)3 mes}U] (1), with potassium spheres in the presence of a slight excess of 2.2.2-cryptand, affords the quantitative conversion of 1 into the uranium(II) monoarene complex [K(2.2.2-crypt)][(((Ad,Me) ArO)3 mes)U] (1-K). The molecular and electronic structure of 1-K was established experimentally by single-crystal X-ray diffraction, variable-temperature (1) H NMR and X-band EPR spectroscopy, solution-state and solid-state magnetism studies, and optical absorption spectroscopy. The electronic structure of the complex was further investigated by DFT calculations. The complete body of evidence confirms that 1-K is a uranium(II) monoarene complex with a 5f (4) electronic configuration supported by δ backbonding and that the nearly reversible, room-temperature reduction observed for 1 at -2.495 V vs. Fc/Fc(+) is principally metal-centered.

Published
2014

17. Coordination and redox isomerization in the reduction of a uranium(III) monoarene complex

Author

Dominik P. Halter, Karsten Meyer, Hajime Kameo, Frank W. Heinemann, and Henry S. La Pierre

Subjects
chemistry.chemical_classification, Ligand, Hydride, Inorganic chemistry, chemistry.chemical_element, General Chemistry, General Medicine, Uranium, Redox, Catalysis, chemistry, General chemistry, Polymer chemistry, Cyclic voltammetry, Isomerization, Crown ether
Abstract

Synthetic studies on the redox chemistry of trivalent uranium monoarene complexes were undertaken with a complex derived from the chelating tris(aryloxide)arene ligand ((Ad,Me) ArO)3 mes(3-) . Cyclic voltammetry of [{((Ad,Me) ArO)3 mes}U(III) ] (1) revealed a nearly reversible and chemically accessible reduction at -2.495 V vs. Fc/Fc(+) -the first electrochemical evidence for a formally divalent uranium complex. Chemical reduction of 1 indicates that reduction induces coordination and redox isomerization to form a uranium(IV) hydride, and addition of a crown ether results in hydride insertion into the coordinated arene to afford uranium(IV) complexes. This stoichiometric reaction sequence provides structural insight into the mechanism of arene functionalization at diuranium inverted sandwich complexes.

Published
2014

18. Catching gaseous SO2 in cone-type lanthanide complexes: an unexpected coordination mode for SO2 in f-element chemistry

Author

Karsten Meyer, Paul Benndorf, Peter W. Roesky, Andreas Scheurer, Ralf Köppe, Sophia Schmitt, and Pascual Oña-Burgos

Subjects
Lanthanide, chemistry.chemical_classification, Crystallography, chemistry, Inorganic chemistry, Solid-state, General Chemistry, Catalysis, Coordination complex
Abstract

Easy come, easy go: the first molecular SO(2) complexes of the lanthanides (Ln=Sm, Eu) have been prepared. The compounds can reversibly coordinate gaseous SO(2). Concomitant with the addition and removal of SO(2), the color of the complexes changes reversibly. The structures of the SO(2) compounds could be confirmed in solution and in the solid state.

Published
2011

20. Synthesis of (±)-merrilactone A and (±)-anislactone A

Author

Karsten Meyer, Michael F. Greaney, and Lei Shi

Subjects
Molecular Structure, Stereochemistry, Epoxide, Regioselectivity, Total synthesis, General Chemistry, General Medicine, Ring (chemistry), Catalysis, Illicium, chemistry.chemical_compound, Formal synthesis, Lactones, Merrilactone A, chemistry, Yield (chemistry), Stereoselectivity, Sesquiterpenes
Abstract

The first synthesis of anislactone A (I) (22 steps, 5.7% overall yield) and a formal synthesis of merrilactone A (II) (22 steps to known intermediate III in 2.4% overall, 24 steps to the natural product) through a common route has been completed. The synthesis describes a direct approach to all-chiral carbon-B ring cyclopenatne IV [TBDMS = SiMe2CMe3] using a [2+2] photocycloaddn., regioselective Tiffeneau-Demjanov ring expansion and stereoselective 1,2-addn. as key C-C-bond forming steps. The defining transformation is then the reductive epoxide cleavage-cyclization to form the C9 quaternary center at the heart of the sesquiterpene structure. [on SciFinder(R)]

Published
2010

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