News Release

Versatile, high-speed, and efficient crystal actuation with photothermally resonated natural vibrations

Researchers from Japan observe large bending along with high-speed resonated natural vibrations in anisole crystals when irradiated with pulsed ultraviolet light

Peer-Reviewed Publication

Waseda University

Enhancing the photothermally induced natural vibration of crystals via resonance with UV irradiation

image: Researchers from Japan have demonstrated high-frequency and large resonated natural vibrations in anisole single crystals driven by pulsed UV radiation at the natural vibration frequency of the crystal. Their research has immense potential for advancing the field of soft robotics and versatile actuation technology. view more 

Credit: Dr. Hideko Koshima from Waseda University

Every material possesses a unique natural vibration frequency such that when an external periodic force is applied to this material close to this frequency, the vibrations are greatly amplified. In the parlance of physics, this phenomenon is known as “resonance.” Resonance is ubiquitous in our daily life, and, depending on the context, could be deemed desirable or undesirable. For instance, musical instruments like the guitar relies on resonance for sound amplification. On the other hand, buildings and bridges are more likely to collapse under an earthquake if the ground vibration frequency matches their natural frequency.

Interestingly, natural vibration has not received much attention in material actuation, which relies on the action of mechanically responsive crystals. Versatile actuation technologies are highly desirable in the field of soft robotics. Although crystal actuation based on processes like photoisomerisation and phase transitions have been widely studied, these processes lack versatility since they require specific crystals to work. One way to improve versatility is by employing photothermal crystals, which show bending due to light-induced heating. While promising for achieving high-speed actuation, the bending angle is usually small (<0.5°), making the actuation inefficient.

Now, a team of scientists from Waseda University and Tokyo Institute of Technology in Japan has managed to overcome this drawback with nothing more than the age-old phenomenon of resonated natural vibration. The team, led by Dr. Hideko Koshima from Waseda University in Japan, used 2,4-dinitroanisole β-phase crystals () to demonstrate large-angle photothermally resonated high-speed bending induced by pulsed UV irradiation. Their research was published in Volume 14 of Nature Communications and made available online on March 13, 2023. “Initially, the goal of this research was to create crystals that bend largely due to the photothermal effect. Therefore, we chose 2,4-dinitroanisole (1) β-phase crystal (), which has a large thermal expansion coefficient,” explains Koshima, speaking of the team’s motivation behind the study. “We serendipitously discovered fast and small natural vibration induced by the photothermal effect. Furthermore, we achieved high-speed and large bending by photothermally resonating the natural vibration.”

In their work, the team first cooled a methanol solution of commercially available anisole 1 to obtain hexagonal, rod-shaped single crystals. To irradiate them with UV light, they used a pulsed UV laser with a wavelength of 375 nm and observed the bending response of the crystal using a digital high-speed microscope. They found that the rod-shaped crystals showed, under UV irradiation, a fast natural vibration at 390 Hz with a large photothermal bending of nearly 1°, which is larger than the value of 0.2° previously reported in other crystals. Further, the bending angle due to the natural vibraton increased to nearly 4° when irradiated with pulsed UV light at 390 Hz (same as the crystal’s natural frequency). In addition to this large bending, the team observed a high response frequency of 700 Hz along with the highest energy conversion efficiency recorded till date.

These findings were further confirmed through simulations performed by the team. To their excitement, the simulation results showed excellent agreement with experimental data. “Our findings show that any light-absorbing crystal can exhibit high-speed, versatile actuation through resonated natural vibrations. This can open doors to the applications of photothermal crystals, leading eventually to real-life soft robots with high-speed actuation capability and perhaps a society with humans and robots living in harmony,” concludes Koshima.

 

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Reference

DOI: https://doi.org/10.1038/s41467-023-37086-8

 

 

Authors: Yuki Hagiwara1, Shodai Hasebe1, Hiroki Fujisawa2, Junko Morikawa2, Toru Asahi1,3 & Hideko Koshima3

 

Affiliations:

1Graduate School of Advanced Science and Engineering, Waseda University

2School of Materials and Chemical Technology, Tokyo Institute of Technology

3Research Organization for Nano & Life Innovation, Waseda University

 

About Waseda University
Located in the heart of Tokyo, Waseda University is a leading private research university that has long been dedicated to academic excellence, innovative research, and civic engagement at both the local and global levels since 1882. The University has produced many changemakers in its history, including nine prime ministers and many leaders in business, science and technology, literature, sports, and film. Waseda has strong collaborations with overseas research institutions and is committed to advancing cutting-edge research and developing leaders who can contribute to the resolution of complex, global social issues. The University has set a target of achieving a zero-carbon campus by 2032, in line with the Sustainable Development Goals (SDGs) adopted by the United Nations in 2015.

To learn more about Waseda University, visit https://www.waseda.jp/top/en

 

About Hideko Koshima
Dr. Hideko Koshima is an adjunct researcher at Waseda University. She was a professor at Ehime University before moving to Waseda University several years ago. Her research interests are in solid-state organic photochemistry, material chemistry, and chiral chemistry. Over the last decade, her research has focused on mechanical molecular crystals that are actuated by light and heat.


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