sg:pub.10.1007/s10751-021-01783-x - Springer Nature SciGraph

Article Info

DATE

2021-12-10

AUTHORS

ABSTRACT

The literature on effects of time-dependent hyperfine interactions on perturbed angular correlation (PAC) spectra is dominated by analyses based on models of stochastically fluctuating interactions. The Floquet formalism offers a convenient alternative analysis when interactions have a harmonic time dependence. This is demonstrated in the present work through simulation of PAC spectra due to uniformly rotating electric field gradients (EFGs). Physically, this situation would arise when PAC tracers are embedded in molecules with inertial rotation velocities much larger than molecular collision rates, in which case reorientation of rotation axes would be negligible on the characteristic PAC timescale. The prospect for using PAC to study inertial properties of molecules is explored through simulations with molecules modeled as symmetric, rigid bodies. More... »

PAGES

References to SciGraph publications

1973-08. Time-dependent electric quadrupole interactions in (NH4)3HfF7 in ZEITSCHRIFT FÜR PHYSIK A HADRONS AND NUCLEI

1991-07. Analysis of perturbed angular correlation spectra of metal ions bound to proteins with rotational correlation times in the intermediate region in HYPERFINE INTERACTIONS

2017-11-25. Solid-State NMR Under Ultrafast MAS Rate of 40–120 kHz in EXPERIMENTAL APPROACHES OF NMR SPECTROSCOPY

1976-07. Pac study of molecular reorientation in liquids in HYPERFINE INTERACTIONS

2004-10-18. New Horizons for Magic-Angle Spinning NMR in NEW TECHNIQUES IN SOLID-STATE NMR

1981-06. PAC study of molecular rotational motions in dilute solutions in HYPERFINE INTERACTIONS

1971-06. Determination of nuclear multipole relaxation times by measurements of statistically perturbed angular correlations in ZEITSCHRIFT FÜR PHYSIK A HADRONS AND NUCLEI

1991-11. Rotational correlation times of peptides determined by perturbed angular correlations of γ-rays in EUROPEAN BIOPHYSICS JOURNAL

1976-09. γγ Angular correlations perturbed by randomly reorienting hyperfine fields in ZEITSCHRIFT FÜR PHYSIK A HADRONS AND NUCLEI

Journal

TITLE

Hyperfine Interactions

ISSUE

VOLUME

242

Subjects

FOR: Physical Sciences

FOR: Atomic, Molecular, Nuclear, Particle And Plasma Physics

FOR: Condensed Matter Physics

Author Affiliations

Department of Physics, Geology, and Engineering Technology, Northern Kentucky University, 41099, Highland Heights, KY, USA

Department of Chemistry, University of Copenhagen, 2100, København Ø, Denmark

Identifiers

URI

http://scigraph.springernature.com/pub.10.1007/s10751-021-01783-x

DOI

http://dx.doi.org/10.1007/s10751-021-01783-x

DIMENSIONS

https://app.dimensions.ai/details/publication/pub.1143785380

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