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Supercritical Fluids Help Stabilize Quantum Dot Formation: Applications for Photoluminescent Materials; Bio-Imaging; Photonics and Optoelectronics

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Supercritical Fluids Help Stabilize Quantum Dot Formation: Applications for Photoluminescent Materials; Bio-Imaging; Photonics and Optoelectronics

Supercritical Fluids Help Stabilize Quantum Dot Formation: Applications for Photoluminescent Materials; Bio-Imaging; Photonics and Optoelectronics

Supercritical QD ToyohashiTech-supercritical-CO2-quantum-dot-303705iufqusfpiufpqxa8Researchers have used supercritical CO2—CO2 at a temperature and pressure above the critical point such that distinctions between the liquid and gas phase do not exist—to stabilize the production of quantum dots (QDs). Their research has been published in The Journal of Supercritical Fluids and selected by the editor-in-chief as a featured article.
Semiconductor nanocrystals known as QDs are increasingly being used as photoluminescent materials in bio-imaging, photonics, and optoelectronic applications. In these applications, QDs must have stable photoluminescence properties, which is achieved by chemically modifying the surface of the QDs.
However, chemical modification of the surface typically requires large amounts of organic solvents that are harmful to the environment. To solve this problem, many researchers have attempted to synthesize polymer-nanoparticle composites by using supercritical fluid (SCF)-based technology. Supercritical CO2 has emerged as the most extensively studied SCF medium, because it is readily available, inexpensive, nonflammable, and environmentally benign.
Toyohashi Tech researchers, in cooperation with researchers at the National Institute of Technology, Kurume College, have investigated the formation of nanostructured material using supercritical CO2. They have demonstrated the formation of composite nanoparticles of luminescent ZnO QDs and polymers by dispersion polymerization in supercritical CO2. As a result of the supercritical-CO2-assisted surface modification of QDs, the QDs were well dispersed in the polymer matrix and showed high luminescence.
“Unfortunately, the photoluminescence properties of pristine luminescent QDs were quenched in supercritical CO2. The surface structure of the QDs was destroyed by supercritical CO2,” explained Associate Professor Kiyoshi Matsuyama from the National Institute of Technology, Kurume College.
“We found that the quenching of ZnO QDs could be prevented by coating with silica to obtain PMMA-ZnO composite QDs with high luminescence using a supercritical-CO2-assisted surface modification with polymer.”
The research shows that the supercritical-fluid-assisted process provides an environmentally benign route for producing stabilized luminescent materials.
The article can be found at: Matsuyama et al. (2015) Formation of Poly(Methyl Methacrylate)-ZnO Nanoparticle Quantum Dot Composites by Dispersion Polymerization in Supercritical CO2.

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