Superconducting properties of thin film Nb1-xTixN studied via the NMR of implanted 8Li

Abstract

We report measurements of the normal-state and superconducting properties of thin-film Nb1-xTixN using 8Li β-detected nuclear magnetic resonance (β-NMR). In these experiments, radioactive 8Li+ probes were implanted 21 nm below the surface of a Nb1-xTixN(91 nm) film in Nb0.75Ti0.25N(91 nm)/AlN(4 nm)/Nb and its NMR response recorded (via 8Li's β-emissions) between 4.6 K and 270 K in a 4.1 T field applied normal to its surface. Resonance measurements reveal wide, symmetric lineshapes at all temperatures, with significant additional broadening below the film's superconducting transition temperature Tc(0 \; T) = 15.4 0.7 K due to vortex lattice formation. Fits to a broadening model find a magnetic penetration depth λ(0 \; K)= 180.57 0.30 nm and upper critical field Bc2(0 \; K)= 18 4 T, consistent with literature estimates. Spin-lattice relaxation (SLR) measurements find a Korringa response at low temperatures, with dynamic (i.e., thermally activated) contributions dominating above 100 K. Below Tc, we observe a small Hebel-Slichter coherence peak characterized by a superconducting energy gap (0 \; K) = 2.60 0.12 meV and modest Dynes-like broadening. Our measurements suggest a gap ratio 2(0 \; K)/kBTc(0 \; T) = 3.92 0.25, consistent with strong-coupling behavior. Sources for the dynamic high-T relaxation are suggested.