Elastic/anelastic behaviour during the phase transition in spinel LiMn2O4

Abstract

Both the Young`s modulus sound velocity (V_E) and the internal friction (Q^-1) have been measured for a polycrystalline sample of LiMn₂O₄ in the temperature range between 35 and 350 K, using a vibrating-reed technique. The resonance frequency (f_r) employed for the measurement ranged from 0.81 kHz to 2.69 kHz at 300 K. At f_r(300 K)=0.81 kHz, as temperature is lowered from 350 K, V_E decreases down to 225 K (T_A) Then, V_E increases rapidly but monotonically with lowering temperature, though the magnitude of the slope (-dV_E/dT) reduces. The overall increase in the velocity between T_A and 100 K is about 68%. In the Q^-1-versus-T curve, a large peak is clearly observed at around 210 K, as is the forming of a large shoulder on the low-temperature side; additionally, there exists a small Q^-1 peak at around 120 K, though V_E indicates no significant change at around 120 K. Furthermore, both the V_E-versus-T curve and the Q^-1-versus-T curve shift toward the higher-temperature side, by ~45 K and ~25 K, as f_r(300 K) is increased from 1.32 kHz to 2.69 kHz. The observed elastic anomalies suggest that a phase transition occurs at temperatures below 290 K. This phase transition is probably due to an ordering of Mn³⁺ and Mn⁴⁺ ions on the octahedral 16d site in the spinel lattice. On the other hand, the origin of the Q^-1 peak is considered to lie in a stress-induced relaxation of the distributions of Mn ions or Li ions.