Abstract

We monitor the localization of donor wave functions when going from the bulk to nanoscales by electrically detected magnetic resonance of P-doped Si nanocrystal networks. Analysis of the P hyperfine splitting shows that for nanocrystals with radii above $\ensuremath{\sim}6\text{ }\text{nm}$ donor localization is dominated by a reduction in dielectric screening relative to the bulk rather than by quantum confinement. Screening effects become negligible only for radii below $\ensuremath{\sim}2\text{ }\text{nm}$, where quantum confinement dominates. Thus, hyperfine interactions can serve as sensitive probes to study basic properties of doped nanocrystals and provide data to critically test theoretical models.