In the search for solutions to ever-worsening environmental problems, such as the depletion of fossil fuels and climate change, many have turned to the potential of thermoelectric materials to generate power. These materials exhibit what is known as the thermoelectric effect, which creates a voltage difference when there is a temperature gradient between the material's sides. This phenomenon can be exploited to produce electricity using the enormous amount of waste heat that human activity generates, such as that from automobiles and thermal power plants, thereby providing an eco-friendly alternative to satisfy our energy needs.
Magnesium silicide (Mg2Si) is a particularly promising thermoelectric material with a high "figure of merit" (ZT)--a measure of its conversion performance. Though scientists previously noted that doping Mg2Si with a small amount of impurities improves its ZT by increasing its electrical conductivity and reducing its thermal conductivity, the underlying mechanisms behind these changes were unknown--until now.
In a recent joint study published as a featured article in Applied Physics Letters, scientists from Tokyo University of Science (TUS), the Japan Synchrotron Radiation Research Institute (JASRI), and Shimane University, Japan, teamed up to uncover the mysteries behind the improved performance of Mg2Si doped with antimony (Sb). Dr Masato Kotsugi from TUS, who is corresponding author of the study, explains their motivation: "Although it has been found that Sb impurities increase the ZT of Mg2Si, the resulting changes in the local structure and electronic states that cause this effect have not been elucidated experimentally. This information is critical to understanding the mechanisms behind thermoelectric performance and improving the next generation of thermoelectric materials."
But how could they analyze the effects of Sb impurities on Mg2Si at the atomic level? The answer lies in extended X-ray absorption fine structure (EXAFS) analysis and hard X-ray photoelectron spectroscopy (HAXPES), as Dr Masato Kotsugi and Mr Tomoyuki Kadono, who is first author of the study, explain: "EXAFS allows us to identify the local structure around an excited atom and has strong sensitivity toward dilute elements (impurities) in the material, which can be precisely identified through fluorescence measurements. On the other hand, HAXPES lets us directly investigate electronic states deep within the bulk of the material without unwanted influence from surface oxidation." Such powerful techniques, however, are not performed using run-of-the-mill equipment. The experiments were conducted at SPring-8, one of the world's most important large X-ray synchrotron radiation facilities, with the help of Dr Akira Yasui and Dr Kiyofumi Nitta from JASRI.
The scientists complemented these experimental methods with theoretical calculations to shed light on the exact effects of the impurities in Mg2Si. These theoretical calculations were carried out by Dr Naomi Hirayama of Shimane University. "Combining theoretical calculations with experimentation is what yielded unique results in our study," she says.
The scientists found that Sb atoms take the place of Si atoms in the Mg2Si crystal lattice and introduce a slight distortion in the interatomic distances. This could promote a phenomenon called phonon scattering, which reduces the thermal conductivity of the material and in turn increases its ZT. Moreover, because Sb atoms contain one more valence electron than Si, they effectively provide additional charge carriers that bridge the gap between the valence and conduction bands; in other words, Sb impurities unlock energy states that ease the energy jump required by electrons to circulate. As a result, the electrical conductivity of doped Mg2Si increases, and so does its ZT.
This study has greatly deepened our understanding of doping in thermoelectric materials, and the results should serve as a guide for innovative materials engineering. Dr Tsutomu Iida, lead scientist in the study, says: "In my vision of the future, waste heat from cars is effectively converted into electricity to power an environment-friendly society." Fortunately, we might just be one step closer to fulfilling this dream.
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About the Tokyo University of Science
Tokyo University of Science (TUS) is a well-known and respected university, and the largest science-specialized private research university in Japan, with four campuses in central Tokyo and its suburbs and in Hokkaido. Established in 1881, the university has continually contributed to Japan's development in science through inculcating the love for science in researchers, technicians, and educators.
With a mission of "Creating science and technology for the harmonious development of nature, human beings, and society", TUS has undertaken a wide range of research from basic to applied science. TUS has embraced a multidisciplinary approach to research and undertaken intensive study in some of today's most vital fields. TUS is a meritocracy where the best in science is recognized and nurtured. It is the only private university in Japan that has produced a Nobel Prize winner and the only private university in Asia to produce Nobel Prize winners within the natural sciences field.
Website: https://www.tus.ac.jp/en/mediarelations/
About Associate Professor Masato Kotsugi from Tokyo University of Science
Dr Masato Kotsugi graduated from Sophia University, Japan, in 1996 and then received a PhD from the Graduate School of Engineering Science at Osaka University in 2001. He joined the Tokyo University of Science in 2015 as a lecturer and became an Associate Professor in the Department of Materials Engineering in 2018. Dr Kotsugi and students at his laboratory conduct cutting edge research on high-performance materials with the aim of creating a green energy society. He has published over 110 refereed papers and is currently interested in solid-state physics, magnetism, synchrotron radiation, and materials informatics.
Funding information
This research was partly supported by KAKENHI, JSPS.
Journal
Applied Physics Letters