Engineering

2017-12-14

Thermoelectric (TE) materials could play a key role in future technologies. Although the applications of these remarkable compounds have long been explored, they are mostly limited to high-temperature devices. Recently, researchers at Osaka University, in collaboration with Hitachi, Ltd., developed a new TE material with an improved power factor at room temperature. Their study, published in Physica Status Solidi RRL, could help bring these materials out of the high-temperature niche and into the mainstream.



TE materials display the thermoelectric effect: apply heat on one side, and an electric current starts to flow. Conversely, run an external current through the device, and a temperature gradient forms; i.e., one side becomes hotter than the other. By interconverting heat and electricity, TE materials can be used as either power generators (given a heat source) or refrigerators (given a power supply).



The ideal TE material combines high electrical conductivity, allowing the current to flow, with low thermal conductivity, which prevents the temperature gradient from evening out. The power generation performance mainly depends on the “power factor,” which is proportional to both electrical conductivity and a term called the Seebeck coefficient.



“Unfortunately, most TE materials are often based on rare or toxic elements,” according to study co-author Sora-at Tanusilp. “To address this, we combined silicon – which is common in TE materials – with ytterbium, to create ytterbium silicide [YbSi 2 ]. We chose ytterbium over other metals for several reasons. First, its compounds are good electrical conductors. Second, YbSi 2 is non-toxic. Moreover, this compound has a specific property called valence fluctuation that make it a good TE material at low temperatures.”



The first advantage of YbSi 2 is that the Yb atoms occupy a mixture of valence states, both +2 and +3. This fluctuation, also known as Kondo resonance, increases the Seebeck coefficient with keeping metal-like high electrical conductivity at low temperature, and therefore the power factor.



Second, YbSi 2 has an unusual layered structure. While the Yb atoms occupy crystal planes similar to pure Yb metal, the Si atoms form hexagonal sheets between those planes, resembling the carbon sheets in graphite. This blocks the conduction of heat through the material, and therefore keeps the thermal conductivity down, preserving the temperature gradient. The researchers believe that heat conduction is further suppressed by controlling the structure in nanoscale and traces of impurities and other defects.



The result is an encouragingly high power factor of 2.2 mWm-1K-2 at room temperature. This is competitive with conventional TE materials based on bismuth telluride. As corresponding author of this study Ken Kurosaki explains, “The use of Yb shows we can reconcile the conflicting needs of TE materials through carefully selecting the right metals. Room-temperature TEs, with moderate power, can be seen as complementary to the conventional high-temperature, high-power devices. This could help unlock the benefits of TE in everyday technology.”

Abstract

Metal silicide-based thermoelectric (TE) materials have attracted attention in the past two decades, because they are less toxic, with low production cost and high chemical stability. Here, we study the TE properties of ytterbium silicide YbSi 2 with a specific layered structure and the mixed valence state of Yb2+ and Yb3+. YbSi 2 exhibits large Seebeck coefficient, S, accompanied by high electrical conductivity, σ, leading to high power factor, S2σ, of 2.2mWm-1K-2 at room temperature, which is comparable to those of state-of-the-art TE materials such as Bi 2 Te 3 and PbTe. Moreover, YbSi 2 exhibits high Grüneisen parameter of 1.57, which leads to relatively low lattice thermal conductivity, κ lat , of 3.0Wm-1K-1 at room temperature. The present study reveals that YbSi 2 can be a good candidate of TE materials working near room temperature.

Figure 1. (a) Three-dimensional crystal structure of YbSi 2 , (b) view along the a-axis, and (c) along the c-axis. (© 2017 Kurosaki et al. Phys. Status Solidi RRL 2017, 1700372. doi: 10.1002/pssr.201700372)

Figure 2. Temperature dependences of (a) the Seebeck coefficient S, (b) electrical conductivity σ, (c) power factor S2σ for YbSi 2 . The reported data for Bi 2 Te 3 -based alloy are shown as solid lines for comparison. (© 2017 Kurosaki et al. Phys. Status Solidi RRL 2017, 1700372. doi: 10.1002/pssr.201700372)

This research was funded by part of a grant for the project "Scientific Innovation for Energy Harvesting Technology," under the Strategic Basic Research Programs (CREST) of the Japan Science and Technology Agency (JST).

To learn more about this research, please view the full research report entitled "Ytterbium silicide (YbSi 2 ): A promising thermoelectric material with a high power factor at room temperature" at this page of Rapid Research Letter.

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