Bi2O2Se is an emerging oxyselenide semiconductor, noted for its promising thermoelectric properties and excellent chemical stability, and it is often regarded as an n-type counterpart to p-type BiCuSeO. However, its intrinsic thermoelectric figure of merit (zT) is severely limited by low electron concentration and high thermal conductivity. In this work, we employed Cl element as donator dopant to substantially enhance the carrier concentration. The room-temperature carrier concentration of Bi2O2Se0.98Cl0.02 thereby reached 2.70 × 1020 cm−3, representing an improvement of two orders of magnitude compared to that of pristine Bi2O2Se. Subsequently, multiple hot-pressing cycles were applied to the optimized composition Bi2O2Se0.98Cl0.02. The process induced significant grain refinement, and the resulting high density of grain boundaries effectively suppressed the lattice thermal conductivity, reducing it to 0.95 W·m−1·K−1 at 823 K. Eventually, a maximum zT of 0.24 was achieved at 823 K for the three-time hot-pressed Bi2O2Se0.98Cl0.02 sample, representing a 71% improvement compared with the pristine Bi2O2Se sample prepared by single hot-pressing (zT = 0.14 at 823 K). This work provides a new strategy for enhancing the thermoelectric performance of oxyselenide through the synergistic regulation of doping and microstructure.
Chen et al. (Mon,) studied this question.