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4.3 Longitudinal Field: T₁ Relaxation of Mu@C₆₀

**Figure 4.21:** Single exponential relaxation of Mu@C₆₀ in a longitudinal applied field of 1.0 T. The fits shown are to a common amplitude exponential relaxation.
$\begin{figure} \begin{center} \mbox{ \epsfig {file=na2ex.ps,width=\textwidth} }\end{center}\end{figure}$

The relaxation of Mu@C₆₀ in high LF ( $B \geq 0.75T$ ) is found to be single exponential, e.g. Fig. 4.21. The relaxation rates exhibit essentially temperature independent (T₁T)^-1 behaviour between about 50K and T_c for each of the systems, Rb₃, K₃, and Na₂Cs. In Rb₃C₆₀ we find no sample dependence, but in Na₂CsC₆₀ we find a significant difference between two runs on the same sample which we infer to be a quench-rate dependence. We thus postpone discussion of the temperature dependence in Na₂CsC₆₀ to section VII.B.

4.3.1 T₁(T) in Rb₃C₆₀ and K₃
4.3.2 T₁(T) and Quench Rate Dependence in Na₂Cs

4.3 Longitudinal Field: T1 Relaxation of Mu@C60

4.3 Longitudinal Field: T₁ Relaxation of Mu@C₆₀