Tin telluride: a weakly co-elastic metal

Abstract

We report resonant ultrasound spectroscopy (RUS), dilatometry/magnetostriction, magnetotransport, magnetization, specific heat, and 119Sn M\"ossbauer spectroscopy measurements on SnTe and Sn0.995Cr0.005Te. Hall measurements at T=77 K indicate that our Bridgman-grown single crystals have a p-type carrier concentration of 3.4 × 1019 cm-3 and that our Cr-doped crystals have an n-type concentration of 5.8 × 1022 cm-3. Although our SnTe crystals are diamagnetic over the temperature range 2\, K ≤ T ≤ 1100\, K, the Cr-doped crystals are room temperature ferromagnets with a Curie temperature of 294 K. For each sample type, three-terminal capacitive dilatometry measurements detect a subtle 0.5 micron distortion at Tc ≈ 85 K. Whereas our RUS measurements on SnTe show elastic hardening near the structural transition, pointing to co-elastic behavior, similar measurements on Sn0.995Cr0.005Te show a pronounced softening, pointing to ferroelastic behavior. Effective Debye temperature, θD, values of SnTe obtained from 119Sn M\"ossbauer studies show a hardening of phonons in the range 60--115K (θD = 162K) as compared with the 100--300K range (θD = 150K). In addition, a precursor softening extending over approximately 100 K anticipates this collapse at the critical temperature, and quantitative analysis over three decades of its reduced modulus finds C44/C44=A|(T-T0)/T0|- with = 0.50 0.02 , a value indicating a three-dimensional softening of phonon branches at a temperature T0 75 K, considerably below Tc. We suggest that the differences in these two types of elastic behaviors lie in the absence of elastic domain wall motion in the one case and their nucleation in the other.