Abstract
Abstract
Advancements in high-temperature thermoelectric (TE) materials have been substantial, yet identifying promising near-room-temperature candidates for efficient power generation from low-grade waste heat or TE cooling applications has become critical but proven exceedingly challenging. Bismuth oxyselenide (Bi2O2Se) emerges as an ideal candidate for near-room-temperature energy harvesting due to its low thermal conductivity, high carrier mobility and remarkable air-stability. In this study, the TE properties of few-layer Bi2O2Se over a wide temperature range (20–380 K) are investigated, where a charge transport mechanism transitioning from polar optical phonon to piezoelectric scattering at 140 K is observed. Moreover, the Seebeck coefficient (S) increases with temperature up to 280 K then stabilizes at
∼
−
200 μV K−1 through 380 K. Bi2O2Se demonstrates high mobility (450 cm2V−1s−1) within the optimum power factor (PF) window, despite its
T
−
1.25
dependence. The high mobility compensates the minor reduction in carrier density n
2D hence contributes to maintain a robust electrical conductivity
∼
3 × 104 S m−1. This results in a remarkable PF of 860 μW m−1K−2 at 280 K without the necessity for gating (V
g = 0 V), reflecting the innate performance of the as-grown material. These results underscore the considerable promise of Bi2O2Se for room temperature TE applications.