Methods to improve thermal conductivity with nanotechnologies and to synthesize TE material from chalcogens and transition metals.
About
Thermoelectric (TE) generator, converting waste heat to electricity, has received increasing attention due to their role in reducing CO2 and greenhouse emission. The efficiency of TE generator relies on TE materials with both high electrical conductivity and low thermal conductivity, so the material can generate a large voltage but remain hot at one side and cold at the other side. The efficiency of the TE material can be determined by the dimensionless thermoelectric figure-of-merit (ZT), where a ZT value of about 1 has been a benchmark for many thermoelectric materials. The higher the ZT the more efficient the material is. Current common TE materials, including bismuth telluride (Bi2Te3), lead telluride (PbTe), and silicon germanium (SiGe), are all very expensive compounds due to the rare elements inside. Therefore, high efficiency and cost-effective TE material is desired to fill the need. Invention: Our inventors at Boston College have developed several novel TE materials through nanocomposite approach using ball milling and hot pressing. They have improved the peak ZT of Half-Heuslers to be 0.8 at 700 °C. They also developed another p-type TE material, Tl0.02Pb0.98Te1-xSexSi0.02Naz (x has a value from 0 to 1, z has a value of 0.015, 0.020, or 0.025), with strong mechanical strength and yield higher ZT values of ~1.7 at 770 K, which enables the application of such materials in waste heat recovery at temperature close to 500 o C. In addition, our inventors have developed methods to improve thermal conductivity with nanotechnologies and to synthesize TE material from chalcogens and transition metals. Features/Advantages: Very high ZT ~1.7 at 500o C. With good mechanical property. The preparation process is easy to be controlled. Applications: Battery Automobile industry Thermoelectric generator Military and aerospace Publication: • Yan, Xiao, et al. "Enhanced thermoelectric figure of merit of p-type half-Heuslers." Nano letters 11.2 (2010): 556- 560. • Zhang, Qinyong, et al. "Effect of silicon and sodium on thermoelectric properties of thallium-doped lead telluride-based materials." Nano letters 12.5 (2012): 2324-2330. Lead Inventor: Zhifeng Ren , Ph.D., Former Professor of Physics, Boston College Patent Information: • BC2011.003/ren: Novel thermoelectric material based on Half-Heuslers: Patent Issued (US 9,048,004) • BC2012.021/ren: Novel thermoelectric material based on Tl0.02Pb0.98Te1-xSexSi0.02Naz: Patent Issued (US 9,099,601) • BC2012.024/ren: Methods of synthesizing thermoelectric materials from chalcogens and transition metals: Patent Issued (US 9,306,145) Licensing Status: Available for exclusive or non-exclusive license Looking for Partners: For sponsored collaboration research to develop and commercialize this invention