Substrate temperature effects on structure and thermoelectric transport in DC-sputtered Bi2Te3 thin films
摘要
The thermoelectric performance of Bi₂Te₃ thin films is highly sensitive to deposition temperature because substrate heating simultaneously controls microstructure, stoichiometry, and charge transport. Here, ~ 450 nm Bi₂Te₃ films were deposited on glass by single-target DC magnetron sputtering while varying the substrate temperature from room temperature to 300 °C (RT, 100 °C, 200 °C, 300 °C). FESEM reveals progressive grain coarsening and improved grain connectivity with increasing temperature, while cross-sectional imaging confirms a comparable film thickness across all samples. EDS shows a monotonic Te-loss trend at elevated substrate temperatures, indicating increasing deviation from stoichiometric Bi₂Te₃. XRD confirms crystalline Bi₂Te₃ formation for all conditions and shows systematic peak shifts/lattice-spacing trends with temperature; no distinct elemental Bi or Te peaks are detected within measurement limits. Hall and transport measurements demonstrate that electrical conductivity increases with substrate temperature, whereas the Seebeck response decreases in magnitude, reflecting the expected conductivity–thermopower trade-off as composition and carrier transport evolve. The power factor (