Local electronic and magnetic properties of the doped topological insulators Bi2Se3:Ca and Bi2Te3:Mn investigated using ion-implanted 8Li β-NMR

Abstract

We report β-detected nuclear magnetic resonance (β-NMR) measurements in Bi2Se3:Ca (BSC) and Bi2Te3:Mn (BTM) single crystals using 8Li+ implanted to depths on the order of 100 nm. Above 200 K, spin-lattice relaxation (SLR) reveals diffusion of 8Li+, with activation energies of 0.4 eV ( 0.2 eV) in BSC (BTM). At lower temperatures, the nuclear magnetic resonance (NMR) properties are those of a heavily doped semiconductor in the metallic limit, with Korringa relaxation and a small, negative, temperature-dependent Knight shift in BSC. From this, we make a detailed comparison with the isostructural tetradymite Bi2Te2Se (BTS) [McFadden et al., Phys Rev. B 99, 125201 (2019)]. In the magnetic BTM, the effects of the dilute Mn moments predominate, but remarkably the 8Li signal is not wiped out through the magnetic transition at 13 K, with a prominent critical peak in the SLR that is suppressed in a high applied field. This detailed characterization of the 8Li NMR response is an important step towards using depth-resolved β-NMR to study the low-energy properties of the chiral topological surface state (TSS). With the bulk NMR response now established in several Bi2Ch3 tetradymite topological insulators (TIs), the prospect of directly probing their chiral TSS using the depth resolution afforded by β-NMR remains strong.