Spin Relaxation Times of Single-Wall Carbon Nanotubes

Abstract

We have measured temperature (T)- and power-dependent electron spin resonance in bulk single-wall carbon nanotubes to determine both the spin-lattice and spin-spin relaxation times, T1 and T2. We observe that T1-1 increases linearly with T from 4 to 100 K, whereas T2-1 decreases by over a factor of two when T is increased from 3 to 300 K. We interpret the T1-1 T trend as spin-lattice relaxation via interaction with conduction electrons (Korringa law) and the decreasing T dependence of T2-1 as motional narrowing. By analyzing the latter, we find the spin hopping frequency to be 285 GHz. Last, we show that the Dysonian lineshape asymmetry follows a three-dimensional variable-range hopping behavior from 3 to 20 K; from this scaling relation, we extract a localization length of the hopping spins to be 100 nm.