Converting Visible Light to UVC: Lanthanide Upconversion Nano-Phosphors for Light-Activated Biocidal Surface Development
Georgia Tech Research Corporation, Atlanta GA
Investigators
Abstract
Lanthanide-doped upconversion phosphor (UCP) materials can absorb one or more low-energy photons and subsequently emit one higher-energy, lower-wavelength photon via a unique photoluminescence process called upconversion. UCP nanocrystals that are capable of converting IR radiation to visible light have seen intensive research in the past decade and have already begun to emerge in solar energy and biomedical applications. We herein recognize the great potential for exploiting UCP nanocrystals - that are engineered to convert ordinary visible light into germicidal ultraviolet radiation - in creating highly innovative biocidal surface technologies, i.e., surfaces that inactivate microorganisms when exposed to visible light. Hypothesis. While a handful of visible-to-UV upconversion materials already exist in the literature, their conversion efficiencies are considered too low for practical biocidal applications. However, based on the recent advances made in IR-to-visible light upconversion technology, they hypothesize that (i) sophisticated material design will lead to higher, more practical upconversion efficiencies and enable UV-emission under low-power sunlight or ambient indoor light conditions; and (ii) such improvements can be achieved through careful selection of lanthanide dopant combinations, low vibrational host matrices, and nano-structural optimization. They further hypothesize that surfaces coated with carefully engineered nanocrystalline UV-emitting phosphors will exhibit biocidal effects, providing an effective, cost-efficient, and sustainable alternative to current antimicrobial surfaces for the deterrence of pathogen transfer. Objectives. The primary focus of the proposed research is to explore fundamental nanophosphor design strategies that result in efficient upconversion of broadband visible light into UV photons in the germicidal range and, consequently, effective biocidal action when coated onto surfaces. Approach. Upconversion nanocrystals will be synthesized via sol-gel decomposition and hydrothermal techniques with varying lanthanide dopant combinations, host crystals and nanostructural modifications. The efficiency and mechanisms of energy transfer processes will be gauged using a custom-built high-energy laser photoluminescence spectroscopy. Materials will be characterized using X-ray diffraction analysis, transmission electron microscopy, etc. Biocidal efficacy and biofilm inhibition will be determined via kinetic viability assays and scanning confocal laser microscopy, respectively, using various test microorganisms. Intellectual Merits. The idea of engineering upconversion nanophosphors for light-activated biocidal surface development has never been explored in the literature. The proposed study will provide fundamental, first-step knowledge in UV-emitting upconversion nanophosphor synthesis strategies, material characterization, and environmental technology applicability. This research will also answer fundamental questions regarding: (i) similarities and differences between the well-understood IR-to-visible upconversion and visible-to-UV upconversion processes; and (ii)design aspects that promote the conversion of a broad range of excitation wavelengths. Broader Impacts. The advancement of light conversion materials is a critical forefront in sustainable and green technology, as it allows utilization of renewable energy as well as, in this case, decreased reliance on continuous chemical application. Surfaces which can inherently remain pathogen free are a long sought-after tool for inhibiting pathogen transfer in hospitals,food industry, and public areas, while we additionally envision application to solar water disinfection kits for the developing world. Educating undergraduate and graduate students is an integral part of the proposed project and will provide participating students with exceptional interdisciplinary and collaborative learning experiences in applied solid-state physics/chemistry,material science, nanotechnology, and environmental engineering. The project will also leverage an existing high school student summer internship program.
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