@article{32478,
  author = {Xuemin Shi and Cheng Sun and Zhonglin Bu and Xinyue Zhang and Yixuan Wu and Siqi Lin and Wen Li and Alireza Faghaninia and Anubhav Jain and Yanzhong Pei},
  title = {Revelation of Inherently High Mobility Enables Mg <sub>3</sub>Sb <sub>2</sub>as a Sustainable Alternative to n‐Bi<sub>2</sub>               Te <sub>3</sub>               Thermoelectrics},
  abstract = {<p><span>Over the past years, thermoelectric Mg&nbsp;</span><span>3</span><span>Sb&nbsp;</span><span>2</span><span>&nbsp;alloys particularly in n-type conduction, have attracted increasing attentions for thermoelectric applications, due to the multivalley conduction band, abundance of constituents, and less toxicity. However, the high vapor pressure, causticity of Mg, and the high melting point of Mg&nbsp;</span><span>3</span><span>Sb&nbsp;</span><span>2</span><span>&nbsp;tend to cause the inclusion in the materials of boundary phases and defects that affect the transport properties. In this work, a utilization of tantalum-sealing for melting enables n-type Mg&nbsp;</span><span>3</span><span>Sb&nbsp;</span><span>2</span><span>&nbsp;alloys to show a substantially higher mobility than ever reported, which can be attributed to the purification of phases and to the coarse grains. Importantly, the inherently high mobility successfully enables the thermoelectric figure of merit in optimal compositions to be highly competitive to that of commercially available n-type Bi&nbsp;</span><span>2</span><span>Te&nbsp;</span><span>3</span><span>&nbsp;alloys and to be higher than that of other known n-type thermoelectrics at 300-500 K. This work reveals Mg&nbsp;</span><span>3</span><span>Sb&nbsp;</span><span>2</span><span>&nbsp;alloys as a top candidate for near-room-temperature thermoelectric applications.</span></p>},
  year = {2019},
  journal = {Advanced Science},
  volume = {6},
  pages = {1802286},
  month = {06/2019},
  issn = {2198-3844},
  doi = {10.1002/advs.v6.1610.1002/advs.201802286},
  language = {eng},
}