APS March Meeting 2016
Volume 61, Number 2
Monday–Friday, March 14–18, 2016;
Baltimore, Maryland
Session B21: Single Molecule Magnets
11:15 AM–2:15 PM,
Monday, March 14, 2016
Room: 320
Sponsoring
Units:
GMAG DMP
Chair: Janathan Friedman, Amherst College
Abstract ID: BAPS.2016.MAR.B21.4
Abstract: B21.00004 : Mechanisms of relaxation and spin decoherence in nanomagnets
11:51 AM–12:27 PM
Preview Abstract
Abstract
Author:
Johan Van Tol
(Florida State University, National High Magnetic Field Laboratory, Tallahassee, FL 32310)
Relaxation in spin systems is of great interest with respect to various
possible applications like quantum information processing and storage,
spintronics, and dynamic nuclear polarization (DNP). The implementation of
high frequencies and fields is crucial in the study of systems with large
zero-field splitting or large interactions, as for example molecular magnets
and low dimensional magnetic materials. Here we will focus on the
implementation of pulsed Electron Paramagnetic Resonance (ERP) at multiple
frequencies of 10, 95, 120, 240, and 336 GHz, and the relaxation and
decoherence processes as a function of magnetic field and temperature.
Firstly, at higher frequencies the direct single-phonon spin-lattice
relaxation (SLR) is considerably enhanced, and will more often than not be
the dominant relaxation mechanism at low temperatures, and can be much
faster than at lower fields and frequencies. In principle the measurement of
the SLR rates as a function of the frequency provides a means to map the
phonon density of states.
Secondly, the high electron spin polarization at high fields has a strong
influence on the spin fluctuations in relatively concentrated spin systems,
and the contribution of the electron-electron dipolar interactions to the
coherence rate can be partially quenched at low temperatures[1]. This not
only allows the study of relatively concentrated spin systems by pulsed EPR
(as for example magnetic nanoparticles and molecular magnets), it enables
the separation of the contribution of the fluctuations of the electron spin
system from other decoherence mechanisms.
Besides choice of temperature and field, several strategies in sample
design, pulse sequences, or clock transitions can be employed to extend the
coherence time in nanomagnets. A review will be given of the decoherence
mechanisms with an attempt at a quantitative comparison of experimental
rates with theory.
[1] Takahashi, S.; Hanson, R.; van Tol, J.; Sherwin, M.S. and Awschalom,
D.D. \textit{Phys. Rev. Lett.,~}101, 047601 (2008)
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2016.MAR.B21.4