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Golden future for thermoelectrics

Researchers at TU Wien discover excellent thermoelectric properties of nickel-gold alloys. These can be used to efficiently convert heat into electrical energy.

Three men stand in front of a blackboard, with a periodic table of the elements in the background.

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Michael Parzer, Fabian Garmroudi and Andrej Pustogow (from left), in the background a periodic table showing the electronic structure of all solid elements.

Schmatic drawing of a material, with fire at one end and ice crystals at the other. Electrons move between them.

© Fabian Garmroudi

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Schematic drawing of the thermoelectric effect in nickel-gold alloys.

Periodic table that depicts the electronic structure of all solid elements.

© Fabian Garmroudi, Andrej Pustogow, Michael Parzer

1 of 3 images or videos

Periodic table that depicts the electronic structure of all solid elements.

Thermoelectrics enable the direct conversion of heat into electrical energy - and vice versa. This makes them interesting for a range of technological applications. In the search for thermoelectric materials with the best possible properties, a research team at TU Wien investigated various metallic alloys. A mixture of nickel and gold proved particularly promising. The researchers recently published their results in the renowned journal "Science Advances".

Using thermoelectrics to generate electricity is nothing new. Since the middle of the 20th century, they have been used to generate electrical energy in space exploration, but thermoelectrics are also used in everyday applications such as portable refrigerators. Moreover, they could also be used in industrial environments to convert waste heat into green electricity, to name just one of the potential applications.

How thermoelectricity works

The thermoelectric effect is based on the movement of charged particles that migrate from the hotter to the colder side of a material. This results in an electrical voltage - the so-called thermoelectric voltage - which counteracts the thermally excited movement of the charge carriers. The ratio of the built-up thermoelectric voltage and the temperature difference defines the Seebeck coefficient, named after the German physicist Thomas Johann Seebeck, which is an important parameter for the thermoelectric performance of a material. The important requirement here is that there is an imbalance between positive and negative charges, as they compensate each other.

"Although Seebeck discovered the thermoelectric effect in common metals more than 200 years ago, nowadays metals are hardly considered as thermoelectric materials because they usually have a very low Seebeck coefficient," explains Fabian Garmroudi, first author of the study. On the one hand, metals such as copper, silver or gold have extremely high electrical conductivity; on the other hand, their Seebeck coefficient is vanishingly small in most cases.

Nickel-gold alloys with outstanding properties

Physicists from the Institute of Solid State Physics (TU Wien) have now succeeded in finding metallic alloys with high conductivity and an exceptionally large Seebeck coefficient. Mixing the magnetic metal nickel with the noble metal gold radically changes the electronic properties. As soon as the yellowish colour of gold disappears when about 10 % nickel is added, the thermoelectric performance increases rapidly. The physical origin for the enhanced Seebeck effect is rooted in the energy-dependent scattering behavior of the electrons - an effect fundamentally different from semiconducting thermoelectrics. Due to the particular electronic properties of the nickel atoms, positive charges are scattered more strongly than negative charges, resulting in the desired imbalance and hence a high thermoelectric voltage.

"Imagine a race between two runners, where one person runs on a free track, but the other person has to get through many obstacles. Of course, the person on the free track advances faster than the opponent, who has to slow down and change direction much more often," compares Andrej Pustogow, senior author of the study, the flow of electrons in metallic thermoelectrics. In the alloys studied here, the positive charges are strongly scattered by the nickel electrons, while the negative charges can move practically undisturbed.

Record breaking material

The combination of extremely high electrical conductivity and simultaneously a high Seebeck coefficient leads to record thermoelectric power factor values in nickel-gold alloys, which exceed those of conventional semiconductors by far. "With the same geometry and fixed temperature gradient, many times more electrical power could be generated than in any other known material," explains Fabian Garmroudi. In addition, the high power density may enable everyday applications in the large-scale sector in the future. "Already with the current performance, smartwatches, for instance, could already be charged autonomously using the wearer's body heat," Andrej Pustogow gives as an example.

Nickel-gold is just the beginning

"Even though gold is an expensive element, our work represents a proof of concept. We were able to show that not only semiconductors, but also metals can exhibit good thermoelectric properties that make them relevant for diverse applications. Metallic alloys have various advantages over semiconductors, especially in the manufacturing process of a thermoelectric generator," explains Michael Parzer, one of the lead authors of the study.

The fact that the researchers were able to experimentally show that nickel-gold alloys are extremely good thermoelectrics is no coincidence. "Even before starting our experimental work, we calculated with theoretical models which alloys were most suitable," reveals Michael Parzer. Currently, the group is also investigating other promising candidates that do not require the expensive element gold. 

Original publication

Fabian Garmroudi, Michael Parzer, Alexander Riss, Cédric Bourgès, Sergii Khmelevskyi, Takao Mori, Ernst Bauer, Andrej Pustogow: High thermoelectric performance in metallic NiAu alloys. Science Advances9, adj1611 (2023), https://doi.org/10.1126/sciadv.adj1611, opens an external URL in a new window.

Contact

DI Fabian Garmroudi
Research Unit Functional and Magnetic Materials
TU Wien
+43 1 58801 13173
fabian.garmroudi@tuwien.ac.at

DI Michael Parzer
Research Unit Functional and Magnetic Materials
TU Wien
+43 1 58801 13173
michael.parzer@tuwien.ac.at

Prof. Dr. Andrej Pustogow
Research Unit Functional and Magnetic Materials
TU Wien
+43 1 58801 13128
pustogow@ifp.tuwien.ac.at
www.ifp.tuwien.ac.at/forschung/pustogow-research/home, opens an external URL in a new window

Text:Sarah Link