Halogens in Acetophenones Direct the Hydrogen Bond Docking Preference of Phenol via Stacking Interactions

Phenol is added to acetophenone (methyl phenyl ketone) and to six of its halogenated derivatives in a supersonic jet expansion to determine the hydrogen bonding preference of the cold and isolated 1:1 complexes by linear infrared spectroscopy. Halogenation is found to have a pronounced effect on the docking site in this intermolecular ketone balance experiment. The spectra unambiguously decide between competing variants of phenyl group stacking due to their differences in hydrogen bond strength. Structures where the phenyl group interaction strongly distorts the hydrogen bond are more difficult to quantify in the experiment. For unsubstituted acetophenone, phenol clearly prefers the methyl side despite a predicted sub-kJ/mol advantage which is nearly independent of zero point vibrational energy, turning this complex into a challenging benchmark system for electronic structure methods which include long range dispersion interactions in some way.

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Halogens in Acetophenones Direct the Hydrogen Bond Docking Preference of Phenol via Stacking Interactions

Molecules ◽

10.3390/molecules26164883 ◽

2021 ◽

Vol 26 (16) ◽

pp. 4883

Author(s):

Charlotte Zimmermann ◽

Manuel Lange ◽

Martin A. Suhm

Keyword(s):

Hydrogen Bond ◽

Vibrational Energy ◽

Supersonic Jet ◽

Phenyl Group ◽

Zero Point ◽

Dispersion Interactions ◽

Supersonic Jet Expansion ◽

Benchmark System ◽

Phenyl Ketone ◽

Zero Point Vibrational Energy

Phenol is added to acetophenone (methyl phenyl ketone) and to six of its halogenated derivatives in a supersonic jet expansion to determine the hydrogen bonding preference of the cold and isolated 1:1 complexes by linear infrared spectroscopy. Halogenation is found to have a pronounced effect on the docking site in this intermolecular ketone balance experiment. The spectra unambiguously decide between competing variants of phenyl group stacking due to their differences in hydrogen bond strength. Structures where the phenyl group interaction strongly distorts the hydrogen bond are more difficult to quantify in the experiment. For unsubstituted acetophenone, phenol clearly prefers the methyl side despite a predicted sub-kJ/mol advantage that is nearly independent of zero-point vibrational energy, turning this complex into a challenging benchmark system for electronic structure methods, which include long range dispersion interactions in some way.

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Secondary kinetic deuterium isotope effects on unimolecular cleavage reactions: Zero‐point vibrational energy and qualitative RRKM theory

Mass Spectrometry Reviews ◽

10.1002/mas.21660 ◽

2021 ◽

Author(s):

Lars F. Østergaard ◽

Steen Hammerum

Keyword(s):

Vibrational Energy ◽

Isotope Effects ◽

Zero Point ◽

Rrkm Theory ◽

Deuterium Isotope Effects ◽

Cleavage Reactions ◽

Zero Point Vibrational Energy

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ON THE NECKING-IN PROCESS IN CLUSTER DECAYS

International Journal of Modern Physics A ◽

10.1142/s0217751x90001677 ◽

1990 ◽

Vol 05 (20) ◽

pp. 3901-3928 ◽

Cited By ~ 10

Author(s):

K. DEPTA ◽

J. A. MARUHN ◽

HOU-JI WANG ◽

A. SĂNDULESCU ◽

W. GREINER ◽

...

Keyword(s):

Potential Energy Surfaces ◽

Vibrational Energy ◽

Correction Term ◽

Zero Point ◽

Alpha Decay ◽

Shell Correction ◽

Macroscopic Models ◽

Excellent Description ◽

Energy Surfaces ◽

Zero Point Vibrational Energy

Two new macroscopic models (liquid drop and Yukawa-plus-exponential) describing the decays with emission of large fragments including alpha decay are developed. The proposed shape parametrization consists of two intersecting spheres smoothly joined by a third "rolling sphere". The first two spheres describe asymptotically the charge and mass asymmetries and the third one the necking-in process. It is shown that the potential energy surfaces in the neck and the relative distance between the centers of the spheres (for a given mass and charge fragmentation) lead to different dynamical paths depending on the mass and charge of the emitted fragment. Along the path a phenomenological shell correction term and a zero point vibrational energy are introduced. It is shown that this model gives an excellent description of the present experimental data.

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