Hanbat National University researchers reveal smart transparent woods that block UV and save energy
The transparent wood is not only promising for indoor illumination and a healthy lifestyle, but also protects privacy at night
Hanbat National University Industry–University Cooperation Foundation
image:
The polymer-dispersed liquid crystal (PDLC)-filled switchable thermochromic transparent wood (TW) exhibits outstanding ultraviolet blocking performance for smart windows.
view moreCredit: Dr. Jin Kim from Hanbat National University
Environmentally friendly buildings are highly attractive for sustainable development and efficient energy consumption. Recently, scientists have made significant strides towards the development of energy-efficient smart windows—with features such as optical modulation, high transparency, low thermal conductivity, and ultraviolet (UV) blocking and heat shielding capabilities—to replace traditional glass windows. The smart windows are a lucrative technology to protect household items as well as human health from the adverse effects of UV radiation.
In a recent breakthrough, a team of researchers from the Republic of Korea, led by Professor Sung Ho Song from Kongju National University and Assistant Professor Jin Kim from the Department of Materials Science and Engineering at Hanbat National University, has developed switchable thermochromic transparent woods (TWs) for smart windows by utilizing UV-curable polymer-dispersed liquid crystal (PDLC) into modified woods for the first time. Their novel findings were made available online and have been published in Volume 8, Issue 393, of the journal Advanced Composites and Hybrid Materials on October 16, 2025.
The PDLC/TW-based “passive” smart window fabricated in this study adjusts its visible light transmittance based on temperature at no extra energy cost. Balsa PDLC/TW exhibits a slowly increasing transmittance based on temperature—switching between opaque (28% transmittance) at room temperature and transparent (78% transmittance) at 40 °C—at 550 nm. In this way, it demonstrates energy-autonomous light regulation while requiring zero external electricity.
Moreover, balsa PDLC/TW exhibits near-total UV shielding with outstanding UV-blocking performance. The material blocks nearly 100% of UVA radiation through a unique "J-aggregation" effect, protecting skin and interiors without sacrificing visible light. It also shows almost five times lower thermal conductivity than that of the glass. “With a thermal conductivity of 0.197 W m⁻¹ K⁻¹, our novel bio-composite is nearly five times more insulating than conventional glass, significantly slowing heat loss or gain in buildings,” highlights Dr. Kim.
He further points out the diverse potential applications of their work. “Our innovation is a direct, eco-friendly replacement for glass that provides privacy at night and natural illumination during the day while slashing HVAC energy costs. It is ideal for smart greenhouses to prevent crop scorching by automatically regulating sunlight and maintaining stable internal growing temperatures. Furthermore, the present technology is promising for the development of intelligent wearable health monitors. It can be used as a flexible skin patch that turns transparent when body temperature exceeds 38°C, providing an instant visual health alert without the need for batteries or electronics,” says Dr. Kim.
In the long term, this work can open the doors to carbon-neutral living by making carbon-neutral homes affordable for the average family by replacing power-hungry smart windows with self-managing, wood-based panels. It can further revolutionize food security; smart greenhouses using the proposed next-generation material could stabilize food production in harsh climates by providing optimal, energy-free thermal and light management. Lastly, this technology is expected to pave the way for a new class of low-cost and disposable battery-free medical wearable devices—such as fever-monitoring wristbands—that provide critical health data with zero charging or syncing requirement.
***
Reference
DOI: 10.1007/s42114-025-01481-0
About the institute
Established in 1927, Hanbat National University (HBNU) is a university in Daejeon, South Korea. As a leading national university in the region, HBNU strives to take the lead in solving problems in the local community and solidifying its cooperation with industries. The university’s vision is to become “an Innovation Platform University integrating local community, industry, academia, and research.” With its focus on practical education and regional impact, HBNU continually advances technological solutions grounded in creative thinking and real-world relevance.
Website: https://www.hanbat.ac.kr/eng/
About the author
Dr. Jin Kim is an Assistant Professor in the Department of Materials Science and Engineering at Hanbat National University. His research group specializes in precision design and atomic-level engineering of low-dimensional metal oxides. By strategically tailoring material architectures, his team unlocks novel electronic and optical properties to drive breakthroughs in advanced energy technologies, flexible optoelectronics, and smart device architectures. Dr. Kim completed his postdoctoral training at the Korea Research Institute of Chemical Technology. He received his Ph.D. in Materials Science and Engineering from the Korea Advanced Institute of Science and Technology (KAIST) in 2020.
Journal
Advanced Composites and Hybrid Materials
Method of Research
Experimental study
Subject of Research
Not applicable
Article Title
Polymer dispersed liquid crystals-impregnated switchable thermochromic transparent woods with excellent ultraviolet blocking performance for smart windows
No comments:
Post a Comment