Charles R. Markus scite author profile

The synthesis of a cobalt dihydrogen Co(I)-(H2) complex prepared from a Co(I)-(N2) precursor supported by a monoanionic pincer bis(carbene) ligand, (Mes)CCC ((Mes)CCC = bis(mesityl-benzimidazol-2-ylidene)phenyl), is described. This species is capable of H2/D2 scrambling and hydrogenating alkenes at room temperature. Stoichiometric addition of HCl to the Co(I)-(N2) cleanly affords the Co(III) hydridochloride complex, which, upon the addition of Cp2ZrHCl, evolves hydrogen gas and regenerates the Co(I)-(N2) complex. Furthermore, the catalytic olefin hydrogenation activity of the Co(I) species was studied by using multinuclear and parahydrogen (p-H2) induced polarization (PHIP) transfer NMR studies to elucidate catalytically relevant intermediates, as well as to establish the role of the Co(I)-(H2) in the Co(I)/Co(III) redox cycle.

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Vibrational Excitation Hindering an Ion-Molecule Reaction: The c−C3H2+<

Markus

Asvany

Salomon

et al. 2020

Phys. Rev. Lett.

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Experiments within a cryogenic 22-pole ion trap have revealed an interesting reaction dynamic phenomenon, where rovibrational excitation of an ionic molecule slows down a reaction with a neutral partner. This is demonstrated for the low-temperature hydrogen abstraction reaction c-, where excitation of the ion into the ν 7 antisymmetric C-H stretching mode decreased the reaction rate coefficient toward the products c-Supported by high-level quantum-chemical calculations, this observation is explained by the reaction proceeding through a c-C 3 H 2 þ − H 2 collision complex in the entrance channel, in which the hydrogen molecule is loosely bound to the hydrogen atom of the c-C 3 H 2 þ ion. This discovery enables high-resolution vibrational action spectroscopy for c-C 3 H 2 þ and other molecular ions with similar reaction pathways. Moreover, a detailed kinetic model relating the extent of the observed product depletion signal to the rate coefficients of inelastic collisions reveals that rotational relaxation of the vibrationally excited ions is significantly faster than the rovibrational relaxation, allowing for a large fraction of the ions to be vibrationally excited. This result provides fundamental insight into the mechanism for an important class of chemical reactions, and is capable of probing the inelastic collisional dynamics of molecular ions.

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High-resolution double resonance action spectroscopy in ion traps: vibrational and rotational fingerprints of CH₂NH₂⁺

Markus

Thorwirth

Asvany

2019

Phys. Chem. Chem. Phys.

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HIGH PRECISION ROVIBRATIONAL SPECTROSCOPY OF OH⁺

Markus

Hodges

Perry

et al. 2016

ApJ

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The molecular ion OH+ has long been known to be an important component of the interstellar medium. Its relative abundance can be used to indirectly measure cosmic ray ionization rates of hydrogen, and it is the first intermediate in the interstellar formation of water. To date, only a limited number of pure rotational transitions have been observed in the laboratory making it necessary to indirectly calculate rotational levels from high-precision rovibrational spectroscopy. We have remeasured 30 transitions in the fundamental band with MHz-level precision, in order to enable the prediction of a THz spectrum of OH+. The ions were produced in a water cooled discharge of O2, H2, and He, and the rovibrational transitions were measured with the technique Noise Immune Cavity Enhanced Optical Heterodyne Velocity Modulation Spectroscopy. These values have been included in a global fit of field free data to a 3Σ− linear molecule effective Hamiltonian to determine improved spectroscopic parameters which were used to predict the pure rotational transition frequencies.

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Charles R. Markus

Well-Defined Cobalt(I) Dihydrogen Catalyst: Experimental Evidence for a Co(I)/Co(III) Redox Process in Olefin Hydrogenation

Vibrational Excitation Hindering an Ion-Molecule Reaction: The c−C3H2+<

High-resolution double resonance action spectroscopy in ion traps: vibrational and rotational fingerprints of CH₂NH₂⁺

HIGH PRECISION ROVIBRATIONAL SPECTROSCOPY OF OH⁺

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Charles R. Markus

Well-Defined Cobalt(I) Dihydrogen Catalyst: Experimental Evidence for a Co(I)/Co(III) Redox Process in Olefin Hydrogenation

Vibrational Excitation Hindering an Ion-Molecule Reaction: The c−C3H2+<

High-resolution double resonance action spectroscopy in ion traps: vibrational and rotational fingerprints of CH2NH2+

HIGH PRECISION ROVIBRATIONAL SPECTROSCOPY OF OH+

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High-resolution double resonance action spectroscopy in ion traps: vibrational and rotational fingerprints of CH₂NH₂⁺

HIGH PRECISION ROVIBRATIONAL SPECTROSCOPY OF OH⁺