policy
(LG Electronics CTO Il-Pyung Park (left) and Dean of KAIST Institute Sang Yup Lee)
KAIST and LG Electronics are working together to take the lead in next-generation wireless communications and launched the LG-KAIST 6G Research Center on January 28, 2019.
KAIST Institute has been focusing on developing a new growth engine for the national economy through interdisciplinary research. In particular, its research work in the field of next-generation wireless communication was listed in the National Research and Development Excellence 100 in 2016 and 2017.
LG Electronics has been a global leader in this field for many years. According to TechIPM, the company had the most 4G LTE/LTE-A patents from 2012 to 2016. Also, it first standardized the Cellular Vehicle-to-Everything, which is the core technology for autonomous vehicles.
The new head of the research center, Professor Dong Ho Cho from the School of Electrical Engineering said, “We will work on developing source technology for sixth generation mobile communications, which will enhance national competence and prepare for the future industries.”
CTO of LG Electronics Il-Pyung Park said, “We are hoping to take the lead in the global standardization of sixth generation wireless communications and secure new business opportunities.”
-
research KAIST Develops Retinal Therapy to Restore Lost Vision
Vision is one of the most crucial human senses, yet over 300 million people worldwide are at risk of vision loss due to various retinal diseases. While recent advancements in retinal disease treatments have successfully slowed disease progression, no effective therapy has been developed to restore already lost vision—until now. KAIST researchers have successfully developed a novel drug to restore vision. < Photo 1. (From left) Ph.D. candidate Museong Kim, Professor Jin Woo Kim, a
2025-03-31 -
research KAIST provides a comprehensive resource on microbial cell factories for sustainable chemical production
In silico analysis of five industrial microorganisms identifies optimal strains and metabolic engineering strategies for producing 235 valuable chemicals Climate change and the depletion of fossil fuels have raised the global need for sustainable chemical production. In response to these environmental challenges, microbial cell factories are gaining attention as eco-friendly platforms for producing chemicals using renewable resources, while metabolic engineering technologies to enhance these
2025-03-27 -
research KAIST Captures Protein Reaction in Just Six Milliseconds
Understanding biomolecular processes - such as protein-protein interactions and enzyme-substrate reactions that occur on the microseconds to millisecond time scale is essential for comprehending life processes and advancing drug development. KAIST researchers have developed a method for freezing and analyzing biochemical reaction dynamics within a span of just a few milliseconds, marking a significant step forward in better understanding complex biological reactions. < Photo. (From left)
2025-03-24 -
research KAIST Develops Eco-Friendly, Nylon-Like Plastic Using Microorganisms
Poly(ester amide) amide is a next-generation material that combines the advantages of PET (polyester) and nylon (polyamide), two widely used plastics. However, it could only be produced from fossil fuels, which posed environmental concerns. Using microorganisms, KAIST researchers have successfully developed a new bio-based plastic to replace conventional plastic. KAIST (represented by President Kwang Hyung Lee) announced on the 20th of March that a research team led by Distinguished Professor
2025-03-24 -
research KAIST Captures Hot Holes: A Breakthrough in Light-to-Electricity Energy Conversion
When light interacts with metallic nanostructures, it instantaneously generates plasmonic hot carriers, which serve as key intermediates for converting optical energy into high-value energy sources such as electricity and chemical energy. Among these, hot holes play a crucial role in enhancing photoelectrochemical reactions. However, they thermally dissipate within picoseconds (trillionths of a second), making practical applications challenging. Now, a Korean research team has successfully devel
2025-03-17