Mechanical Engineering News

Solid material that 'upconverts' visible light photons to UV light photons could change how we utilize sunlight

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February 7, 2023

Ultraviolet (UV) light has higher energy photons than visible light and, thus, has more applications. Tokyo Tech researchers have now developed a brilliant innovation—a solid-state material that can stably and efficiently upconvert sunlight- intensity visible light photons to UV light photons. This photon upconversion (UC) material can utilize visible light to successfully drive reactions that would conventionally need UV light, broadening the spectrum of utility for the former.

Low-intensity visible blue light or lower energy photons being converted into higher energy UV photons using a solid film formed on a round glass substrate, developed by researchers at Tokyo Tec

Figure 1.
Low-intensity visible blue light or lower energy photons being converted into higher energy UV photons using a solid film formed on a round glass substrate, developed by researchers at Tokyo Tech
Image Credit: Prof. Yoichi Murakami

The importance of solar power as a renewable energy resource is increasing. Sunlight contains high-energy UV light with a wavelength shorter than 400 nm, which can be broadly used, for example, for photopolymerization to form a resin and activation of photocatalysts to drive reactions that generate green hydrogen or useful hydrocarbons (fuels, sugars, olefins, etc.). The latter of these is often called "artificial photosynthesis." Photocatalytic reaction by UV light to efficiently kill viruses and bacteria is another important application. Unfortunately, only about 4% of terrestrial sunlight falls within the UV range in the electromagnetic spectrum. This leaves a large portion of sunlight spectrum unexploited for these purposes.

Photon upconversion (UC) could be the key to solving this problem. It is the process of converting long-wavelength, low-energy photons (such as those present in visible light) to short-wavelength, high-energy photons (such as those present in UV light) via a process called "triplet-triplet annihilation" (TTA). Previous works in this field have reported visible-to-UV UC using organic solvent solutions that required the solution to be deoxygenated first and then sealed in an airtight container to prevent exposure to oxygen that deactivated and degraded TTA-based photon UC samples. These materials not only lacked photostability in the presence of oxygen but also failed to perform effectively with sunlight-intensity incident light. These issues presented roadblocks in the practical applications of photon UC.

Now, two scientists at Tokyo Tech—Prof. Yoichi Murakami and his graduate student Mr. Riku Enomoto—have come up with a resolution to these problems—a revolutionary solid film that can perform visible-to-UV photon UC for weak incident light (Figure 1) while remaining photostable for an unprecedented amount of time in air. They describe this breakthrough invention in their paper published in the Journal of Materials Chemistry C.別窓 Prof. Murakami explains the novelty of their research. "Our invention will enable the practical utilization of the visible part of low-intensity light, such as sunlight and LED room light, for applications that are effectively done with UV light. And its photostability—demonstrated to be at least over 100 hours, even in the presence of air—is the highest ever reported in any TTA-based photon UC material, regardless of the material form, as long as we could survey."

In addition to this record photostability, these films had an ultralow excitation threshold (only 0.3x the Sun’s intensity) and a high UC quantum yield of 4.3% (normalized UC emission efficiency of 8.6%) —both in the presence of air—making this material one of a kind, since most materials of this class lose their photon UC ability when exposed to air.

To prepare this material, the researchers melted together a sensitizer (i.e., molecular chromophore that can absorb longer-wavelength photons) with a much larger quantity of an annihilator (i.e., organic molecule that received the triplet excited energy from the sensitizer and then caused the TTA process); the combination of the sensitizer and annihilator was selected by the researchers. This bi-component melt was then cooled over a temperature gradient-controlled surface to form a solid-state visible-to-UV photon UC thin film. This novel technique—temperature gradient solidification—is highly controllable and reproducible, which means that it is compatible with realistic industrial processes. Prof. Murakami tells us, "We believe that the temperature-controlled solidification can provide a solid groundwork for developing advanced photon UC films, that too on a solid substrate without using organic solvents, as demonstrated for the first time by this work."

Finally, to demonstrate the visible-to-UV photon UC of the thin film, the researchers used it with a 1-Sun-intensity simulated sunlight consisting only of visible light to successfully cure and solidify a resin that would otherwise require UV light for the same process.

This study presented, for the very first time, a novel class of UC solids with unprecedented photostability that can be realistically used for the upconversion of low-intensity visible light photons into UV light photons in the presence of air. "Our research will not only expand the exploration of a new class of UV-light-generating materials but will also help in substantially broadening the utility of the abundant weak visible light towards applications that are driven by UV light," concludes Prof. Murakami.

  • Reference
Authors : Riku Enomotoa,b and Yoichi Murakamia,b*
Title : Solvent-free temperature gradient melt formation of efficient visible-to-UV photon upconversion organic films with subsolar threshold and over 100 h photostability in air
Journal : Journal of Materials Chemistry C
DOI : 10.1039/D2TC04578H別窓
Affiliations : aLaboratory for Zero-Carbon Energy, Institute of Innovative Research, Tokyo Institute of Technology, Japan
bDepartment of Mechanical Engineering, Tokyo Institute of Technology, Japan

* Corresponding author's email:

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Further Information

Professor Yoichi Murakami

Institute of Innovative Research, Tokyo Institute of Technology


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