Journal ArticleDOI
Rotation dynamics do not determine the unexpected isotropy of methyl radical EPR spectra
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A derivation is presented explaining why there is actually no need for the CH3 radicals to consider additional rotational dynamics in order for the electron to obtain an axially symmetric hf (hyperfine) tensor by considering the simultaneous dipolar couplings of the three protons.Abstract:
A simple first-principles electronic structure computation, further qc (quantum chemistry) computation, of the methyl radical gives three equal hf (hyperfine) couplings for the three protons with the unpaired electron. The corresponding dipolar tensors were notably rhombic and had different orientations and regular magnitude components, as they should, but what the overall A-tensor was seen by the electron spin is a different story! The final g = (2.002993, 2.002993, 2.002231) tensor and the hf coupling results obtained in vacuum, at the B3LYP/EPRIII level of theory clearly indicate that in particular the above A = (-65.19, -65.19, 62.54) MHz tensor was axial to a first approximation without considering any rotational dynamics for the CH3. This approximation was not applicable, however, for the trifluoromethyl CF3 radical, a heavier and nonplanar rotor with very anisotropic hf coupling, used here for comparison. Finally, a derivation is presented explaining why there is actually no need for the CH3 radicals to consider additional rotational dynamics in order for the electron to obtain an axially symmetric hf (hyperfine) tensor by considering the simultaneous dipolar couplings of the three protons. An additional consequence is an almost isotropic A-tensor for the electron spin of the CH3 radical. To the best of our knowledge, this point has not been discussed in the literature before. The unexpected isotropy of the EPR parameters of CH3 was solely attributed to the rotational dynamics and was not clearly separated from the overall symmetry of the species. The present theoretical results allowed a first explanation of the "forbidden" satellite lines in the CH3 EPR spectrum. The satellites are a fingerprint of the radical rotation, helping thus in distinguishing the CH3 reorientation from quantum rotation at very low temperatures.read more
Citations
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Journal ArticleDOI
Electron Paramagnetic Resonance Spectroscopic Study on Nonequilibrium Reaction Pathways in the Photolysis of Solid Nitromethane (CH3NO2) and D3-Nitromethane (CD3NO2)
TL;DR: The detection of the nitromethyl (CH2NO2) radical along with atomic hydrogen (H) demonstrated the existence of a high-energy decomposition pathway, which is closed under collisionless conditions in the gas phase.
Journal ArticleDOI
Methyl Radical in Clathrate Silica Voids. The Peculiar Physisorption Features of the Guest–Host Molecular Dynamics Interaction
TL;DR: The unusual increase of the CH3/SiO2 clathrates EPR spectral width with temperature over approximately 120 K has its origin in repeated angular momentum vector alterations due to frequent collisions with the clathrate void walls between periodical free rotation periods.
Journal ArticleDOI
Low-temperature matrix effects on orientational motion of Methyl radical trapped in gas solids: Angular tunneling vs. libration
TL;DR: In this paper, the lineshape of matrix-isolated methyl radical, CH3, spectra recorded in solid N2O and CO2 was carried out, and reversible temperature-dependent line width anisotropy was observed in both matrices.
Journal ArticleDOI
Quantum Impurity Rotator in a Matrix of Quantum Rotors: Electron Paramagnetic Resonance Dynamics of CH3 in Solid CD4 Matrix
TL;DR: The present study proves the deep impact that a van der Waals matrix may have on the geometry and the rotation levels of a substitutionally trapped quantum impurity rotor, effects that are yet very little known.
Journal ArticleDOI
Rotational States of Methyl Radical Monitored by EPR Line Shape of Matrix-Isolated CH $$_{3}$$ 3 in CO $$_{2}$$ 2 and N $$_{2}$$ 2 O Solids
TL;DR: In this article, the EPR spectra were analyzed using EasySpin and/or SimFonia simulation software and ab-initio computed quantum-chemistry parameters, focusing on two distinguished features of the spectra: the temperature-dependent linewidth anisotropy and the origin of the weak satellite doublets.
References
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Journal ArticleDOI
Ab Initio Methods for the Calculation of NMR Shielding and Indirect Spin-Spin Coupling Constants
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Theory of anisotropic hyperfine interactions in π-electron radicals
TL;DR: Anisotropic proton hyperfine interactions in π-electron radicals are approximated by a magnetic dipole interaction between each proton and an electron spin magnetization that is distributed in 2s and 2p Slater atomic orbitals centred on carbon atoms.
Journal ArticleDOI
Calculation of the G-Tensor of Electron Paramagnetic Resonance Spectroscopy Using Gauge-Including Atomic Orbitals and Density Functional Theory
Georg Schreckenbach,Tom Ziegler +1 more
TL;DR: In this paper, an implementation of the g-tensor of electron paramagnetic resonance (EPR) spectroscopy is presented, based on density functional theory (DFT) and the use of gauge-including atomic orbitals (GIAO).
Journal ArticleDOI
Quantum Effects of Methyl-Group Rotations in Magnetic Resonance: ESR Splittings and Linewidths
TL;DR: In this article, the effects of internal rotations of methyl groups on ESR hyperfine lines are analyzed in terms of a quantum-mechanical description of the motion, where the classical description of rotational averaging is replaced by spin-rotational coupling from a hyperfine operator and rotational relaxation by thermal collisions.