NMR study of optically hyperpolarized phosphorus donor nuclei in silicon

Abstract

We use above-bandgap optical excitation, via a 1047 nm laser, to hyperpolarize the 31P spins in low-doped (ND =6×1015 cm-3) natural abundance silicon at 4.2 K and 6.7 T, and inductively detect the resulting NMR signal. The 30 kHz spectral linewidth observed is dramatically larger than the 600 Hz linewidth observed from a 28Si-enriched silicon crystal. We show that the observed broadening is consistent with previous ENDOR results showing discrete isotope mass effect contributions to the donor hyperfine coupling. A secondary source of broadening is likely due to variations in the local strain, induced by the random distribution of different isotopes in natural silicon. The nuclear spin T1 and the build-up time for the optically-induced 31P hyperpolarization in the natural abundance silicon sample were observed to be 17847 s and 696 s respectively, significantly shorter than the values previously measured in 28Si-enriched samples under the same conditions. We also measured the T1 and hyperpolarization build-up time for the 31P signal in natural abundance silicon at 9.4 T to be 5431 s and 132 s respectively. The shorter build-up and nuclear spin T1 times at high field are likely due to the shorter electron-spin T1, which drives nuclear spin relaxation via non-secular hyperfine interactions. At 6.7 T, the phosphorus nuclear spin T2 was measured to be 16.71.6 ms at 4.2 K, a factor of 4 shorter than in 28Si-enriched crystals. This was observed to further shorten to 1.90.4 ms in the presence of the infra-red laser.