Liu Min, Zhang Xinyue, Ding Wenjun, Pei Yanzhong
Interdisciplinary Materials Research Center, School of Materials Science and Engineering, Tongji University, 4800 Caoan Road, Shanghai 201804, People's Republic of China.
ACS Appl Mater Interfaces. 2024 Jun 19;16(24):31826-31832. doi: 10.1021/acsami.4c05134. Epub 2024 Jun 7.
Thermoelectricity has been considered as the most important solution of generating electricity, particularly from low-grade heat below 300 °C. Despite efforts in recent years on exploring alternative materials to only commercialized BiTe, the practical implementation of these new materials has been hindered by inadequate investigation into device design. Given that the utilization of weldable electrodes offers advantages in technical compatibility for a large-scale assembly of thermoelectric elements into modules, a thorough investigation into the potential of weldable metal electrodes at < 300 °C is imperative. In this work, the diffusion of 11 kinds of thermoelectric materials in common weldable metals (Ni, Fe, Cu, and Ag) was screened. Ag is sorted out as a promising weldable electrode that can directly bond to thermoelectric AgSe in this temperature range, leading to a minimization of an interfacial contact resistivity down to 11 μΩ cm in a design of the Ag/AgSe/Ag structure. The conversion efficiency of ∼3% at Δ of 95 K with an excellent stability indicates AgSe as a top alternative to n-type BiTe for low-grade heat recovery.
热电效应被认为是发电的最重要解决方案,特别是利用低于300°C的低品位热能发电。尽管近年来人们致力于探索替代仅商业化的BiTe的材料,但这些新材料的实际应用因对器件设计的研究不足而受阻。鉴于可焊接电极的使用在将热电元件大规模组装成模块的技术兼容性方面具有优势,因此必须对低于300°C时可焊接金属电极的潜力进行深入研究。在这项工作中,筛选了11种常见热电材料在可焊接金属(镍、铁、铜和银)中的扩散情况。银被筛选为一种有前景的可焊接电极,在该温度范围内可直接与热电材料AgSe结合,在Ag/AgSe/Ag结构设计中,可将界面接触电阻最小化至11μΩ·cm。在95K的温差下,转换效率约为3%,且具有出色的稳定性,这表明AgSe是用于低品位热回收的n型BiTe的首选替代材料。
