Jong-Soo Lee and his research team from the Department of Energy Science & Engin­eering, DGIST, developed a green-emitting Cd-free quantum dot synthesis technology with high color repro­duction rate. The newly developed quantum dot material is expected to be used in various photo­electric devices, including next-generation displays such as AR/VR.

Quantum dots have a high color repro­duction performance and reproduces natural colors, making it suitable for its application in high dynamic range (HDR), which is used in ultra-high definition displays. Moreover, the material has higher color purity and photo­stability than other lumines­cent materials, emerging as the new material for various photo­electric devices, including next-generation displays. The color reproduction performance of QDs improves as the full width at half-maximum (FWHM) of the light-emitting wavelength of QD becomes smaller. Moreover, before the develop­ment of the proposed technology, the technical limit on the FWHM of photo­luminescent (PL) peaks for the green-emitting Cd-Free QDs was 35 nano­meters.

Jong-Soo Lee and his team used a heat-up process to optimize the synthesis of InP-based QDs, and used zinc chloride (ZnCl2) and octanol(1-Octanol) for the stabi­lization of QD surface and succeeded in reducing the FWHM of QD PL peaks to less than 33 nanometers. In addition to achieving 80 % quantum effi­ciency (QE), the research team also succeeded in securing the same level of stability as the existing QDs, which helped in solving the problem of quantum efficiency losses and reduction in stabi­lization.

Lee commented that, “The study proved that Cd-free quantum dots can have FWHM of PL peaks smaller than 30 nanometers, which was known as the technical limit before the intro­duction of proposed technology. Through follow-up studies, we hope to develop eco-friendly QDs with FWHM of PL peaks less than 30 nano­meters as well as QE close to 100 %, thus contri­buting to the next-generation displays and related industries.” (Source: DGIST)

Reference: D. A. Taylor et al.: Importance of Surface Functionalization and Purification for Narrow FWHM and Bright Green-Emitting InP Core–Multishell Quantum Dots via a Two-Step Growth Process, Chem. Mat. 33, 4399 (2021); DOI: 10.1021/acs.chemmater.1c00348

Link: Dept. of Energy Science and Engineering, DGIST, Daegu, Republic of Korea