Spin-lattice relaxation of trivalent praseodymium, terbium, and erbium in anhydrous lanthanum trichloride: Temperature and magnetic field dependence
Bohan, Thomas Lynch
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https://hdl.handle.net/2142/25736
Description
Title
Spin-lattice relaxation of trivalent praseodymium, terbium, and erbium in anhydrous lanthanum trichloride: Temperature and magnetic field dependence
Author(s)
Bohan, Thomas Lynch
Issue Date
1968
Doctoral Committee Chair(s)
Stapleton, H.J.
Department of Study
Physics
Discipline
Physics
Degree Name
Ph.D.
Degree Level
Dissertation
Keyword(s)
spin-lattice relaxation
trivalent praseodymium
terbium
erbium
anhydrous lanthanum trichloride
Language
en
Abstract
We present the results of our measurements of the spinlattice
relaxation rates of several trivalent rare earth ions, in the
temperature range 0.25 - 4.2o
K. We analyze these results within the
framework of the Kronig-Van Vleck-Orbach theory, the main features of
which we derive in a semi-rigorous manner. We used the pulse saturation
method, operating at a microwave frequency of 15.5 GHz. Through
additional measurements of our own and of others on the same samples
at 9 GHz, we were able to check the frequency (or field) dependence
of the relaxation rates. The non-Kramers Pr:LaC13
system was bottlenecked
in the direct region and hence its relaxation rate was essentially
frequency independent. The Kramers system Er:LaC13
showed a direct
process frequency dependence which was very close to the fourth power
law of Van Vleck; the non-Kramers system Tb:LaC13 had a direct
relaxation process which varied with the square of the frequency, a
variation close to that predicted. Actually, the Tb:LaC13.
system is
somewhat unusual in that a crystal field splitting of its ground
doublet results in the composition of its two lowest states being a
function of the magnitude of the applied field. This situation should
result in a fairly strong field dependence for the Raman and Orbach
coefficients, a dependence which is observed experimentally. In
contrast, no frequency dependence was expected or observed for the
Raman and Orbach coefficients for Er:LaC13 ,
The low temperatures used in these experiments were attained
through the use of a helium-three cryostat. The construction of this
cryostat and the associated ESR pulse spectrometer are described in
some detail.
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