Novel durable copper-aluminum-zinc shape memory alloys for energy-efficient refrigeration

The elastocaloric effect is a phenomenon where a material displays a temperature change when it is exposed to a mechanical stress. The change in temperature occurs due to an entropy difference resulting from a martensitic transformation accompanied by material’s crystal structure change under stress. An analogous effect is observed when the rubber band is stretched: its polymer chains line up in an ordered manner, causing its entropy to decrease. This leads to the rubber band discharging heat to its surroundings and becoming warmer. When the rubber band is released, the opposite occurs, and the rubber band cools down.

Like rubber bands, metallic superelastic shape memory alloys (SMAs) can also utilize the elastocaloric effect for cooling. Copper (Cu)-based SMAs consisting of Cu, aluminum (Al), and zinc (Zn) are particularly promising due to their low cost and modest stress demands for triggering the temperature lift. However, Cu-Al-Zn SMAs suffer from cyclical fatigue issues as their coarse crystal grains and numerous grain boundaries are susceptible to fracture from repeated expansion and contraction.

Now, in a study published in the Journal of Physics: Energy on 31 March 2023, Professor Kenjiro Fujimoto from Tokyo University of Science, Professor Ichiro Takeuchi from the University of Maryland, along with researchers from Maryland Energy & Sensor Technologies, USA, have developed a highly durable Cu-Zn-Al SMA capable of withstanding a high number of cyclic loads. “We have been searching for conditions to promote the grain growth of 68Cu-16Al-16Zn alloy to improve its elastocaloric properties,” says Prof. Fujimoto, explaining the motivation behind their study.

Recently,  they reported that subjecting Cu-Al-Mn alloys to repeated heating and cooling across the mixed and high-temperature phases increased the grain size of the material. Intrigued by these findings, the team decided to investigate whether similar phase transformations could enhance the properties of Cu-Zn-Al alloys.

To prepare the Cu-Al-Zn alloys, the researchers combined Cu, Al, and Zn in a carbon crucible. They melted the metals at low pressures to suppress zinc volatilization. Once the alloy was prepared, the researchers cooled and rolled it into 7 mm thick ingots at three different rolling rates (0%, 67%, and 83%, respectively). The phase boundary temperatures of the alloy were then determined using high-temperature X-ray diffraction, which revealed that the phase boundary between the mixed phase and the high-temperature phase occurred between 700°C and 750°C. Based on this, the researchers repeatedly heated and cooled the alloy between 500°C and 900°C.

All the ingots subjected to the heat treatment cycle showed an increase in crystal grain size, with the maximum increase observed in alloys rolled at a rate of 67%. The grain size of the pristine ingot was 2.21 mm, but the average grain size of the heat-treated ingot in this group increased to 11.1 mm.

“The results indicate that heat treatment across the periodic phase boundary, in addition to the 67 % rolling ratio, is effective for single crystalline-like grain growth,” says Prof. Fujimoto. With its larger grains, and fewer grain boundaries, the heat-treated alloy was much more resistant to fracture and was able to withstand more than 60,000 mechanical cycles at 2% strain.

The heat treatment process also resulted in significant improvements in the elastocaloric properties of the Cu-Zn-Al alloy. Compared to previously reported alloys of the same composition, the heat-treated alloy showed latent heat of 6.3 J/g on releasing strain, which is more than double the previously measured value of 2.3 J/g. This indicates that the heat-treated alloy can cool more effectively. Additionally, the alloy exhibited adiabatic temperature difference of +5.9 K and -5.6 K on loading and unloading, respectively, at low cyclic loads (106 MPa).

While rubber band refrigerators have not become mainstream, the elastocaloric effect has the potential to provide innovative cooling solutions. Therefore, developing materials that can achieve this purpose is crucial. In this regard, the heat-treated Cu-Zn-Al alloy exhibits promising properties and can pave the way for efficient and cost-effective cooling systems.

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Reference                    

DOI: https://doi.org/10.1088/2515-7655/acc5b2  

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 Professor Kenjiro Fujimoto from Tokyo University of Science

Dr. Kenjiro Fujimoto is a Professor at Tokyo University of Science’s Faculty of Science and Technology, Department of Pure and Applied Chemistry. He received his Ph.D. in 2001 from Tokyo University of Science. His research interests include Inorganic Materials Chemistry, Solid State Chemistry, Combinatorial Technology, and Materials Informatics. He has over 98 referred papers and 14 Japan patents and two U.S.A patents in these subjects. He is currently involved in the development of combinatorial technology for high-throughput exploration of multi-component inorganic materials and their application for energy/environmental materials and materials informatics.

Funding information

The work at the University of Maryland was supported by the U.S. Department of Energy under DE-EE0009159.