News Release

Omnidirectional color wavelength tuning of stretchable chiral liquid crystal elastomers

Peer-Reviewed Publication

Light Publishing Center, Changchun Institute of Optics, Fine Mechanics And Physics, CAS

Figure | Working principle of the omnidirectional wavelength tuning.

image: 

a) Illustration of the omnidirectional wavelength-tunable color device featuring a mechanochromic chiral liquid crystal elastomer (CLCE) and an electrically deformable dielectric elastomer actuator (DEA). b) Demonstration of reflection wavelength tuning capabilities towards both longer and shorter wavelengths. c-f) Schematic diagrams detailing the operations of the DEA in various modes: (c) contraction mode, (d) stretching mode, and (e) omnidirectional mode by integrating contraction and stretching modes; (f) depicts the helix deformation of the CLCE under each respective tuning mechanism.

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Credit: by Seungmin Nam, Wontae Jung, Jun Hyuk Shin, Su Seok Choi*

In the rapidly evolving field of photonics, a groundbreaking advancement has emerged from Korea, redefining the possibilities of structural color manipulation. Scientists have developed a pioneering technology capable of omnidirectional wavelength tuning, which promises to revolutionize a myriad of tunable photonic applications.

Structural colors, derived from the interaction of light with nano-periodic structures, have long captivated researchers due to their vibrant hues and potential for tunability. Traditional methods, however, have critical technical limitations, primarily allowing for wavelength tuning in only one direction—towards only shorter wavelengths (blue-shifting) according to the triggering method for altering the periodic photonic structure. This constraint has been a significant bottleneck, stifling innovation in the realm of more advanced and higher functional photonic devices.

In a new paper published in Light Science & Application, a team of scientists, led by Professor Su Seok Choi from Pohang University of Science and Technology (POSTECH), Korea and co-workers (Seungmin Nam, Wontae Jung, Jun Hyuk Shin) have developed an omnidirectional color wavelength tuning method for structural colors of chiral photonic elastomers.

Enter the breakthrough innovation: a method for achieving omnidirectional wavelength control, enabling tuning towards both longer and shorter wavelengths with remarkable precision and broadband tuning range. At the heart of this technology lies the strategic manipulation of stretchable and reconfigurable chiral liquid crystal elastomers (CLCEs) in conjunction with dielectric elastomer actuators (DEAs). By expertly controlling the areal expanding and contractive strain of these materials, the researchers have unlocked simultaneous and multidirectional structural color tuning with highly flexibility of wavelength control.

This unprecedented level of control opens up new horizons for photonic applications, ranging from tunable camouflage and optical sensing to the development of electronic skin. The ability to fine-tune wavelengths on demand and across a broad spectrum not only enhances the degree of freedom in photonic system design but also heralds a new era of high-functional, versatile photonic devices.

The significance of this development cannot be overstated. Traditional reconfigurable photonic devices relied heavily on unidirectional wavelength tuning, which, while useful, limited the scope of applications. With the advent of omnidirectional tuning method, devices can now dynamically adjust to a wider range of optical requirements, making them more adaptable and effective in real-world applications.

Moreover, this technology leverages the inherent advantages of CLCEs, such as their high optical quality, ease of fabrication, and scalability while overcoming previous limitations related to wavelength tuning. The novel approach of employing multi-modal electro-active DEAs deformation enabling pitch-expanding and also pitch-shortening deformation of the CLCE and structural color shift towards longer and shorter wavelengths.

This innovation not only signifies a major leap in photonic technology but also underscores the potential of interdisciplinary research in overcoming longstanding challenges. As we stand on the brink of a new age in photonics, the contributions of these scientists from Korea highlight the boundless possibilities that await when curiosity meets ingenuity. The future of smart, tunable photonics is bright, and it is here.


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