Making higher-energy light to fight cancer

The accomplishment, published in Nature Chemistry, brings scientists one step closer to developing minimally invasive photodynamic treatments for cancer. The advance could also hasten new technologies for solar-energy conversion, quantum information, and near-infrared driven photocatalysis.

High energy light, such as ultraviolet laser light, can form free radicals able to attack cancer tissue. Ultraviolet light, however, doesn’t travel far enough into tissues to generate therapeutic radicals close to the tumor site. On the other hand, near-infrared light penetrates deeply but doesn’t have enough energy to generate the radicals.

While photon up-conversion can overcome this limitation, up-converted materials have either low efficiency or are based on toxic materials. Silicon is well-known for being nontoxic, but until now, researchers have not been able to demonstrate that silicon nanocrystals can up-convert photons, leaving this promising cancer treatment tantalizingly out of reach.

A group led by UC Riverside materials science doctoral student Pan Xia attacked this problem by carefully studying the surface chemistry of silicon nanocrystals. The group learned how to attach ligands, which help bind molecules together, to the nanoparticle that are specifically designed to transfer the energy from the nanocrystals to surrounding molecules.

The team then shined laser light into the solution. They found silicon nanocrystals with appropriate surface ligands can rapidly transfer the energy to the triplet state of surrounding molecules. A process called triplet-triplet fusion then converts the low-energy excitation to a high energy one, resulting in the emission of a photon at shorter wavelength, or higher energy, than the one originally absorbed by the nanoparticle.

“We functionalized silicon nanocrystals with anthracene. Then we excited the silicon nanocrystals and found that the energy was efficiently transferred from the nanocrystal, through the anthracene molecules, to the diphenylanthracene in solution,” said Xia. “It means we got higher-energy light.”

“To turn the low-energy photons into high-energy photons, you need to use triplets, you need to use quantum confined nanoparticles, and you need to hold the nanoparticles and the organic molecules very close together. This is how you get the triplets to combine energy to get the high energy photons,” said co-author Ming Lee Tang, an associate professor of chemistry at UC Riverside and Xia’s dissertation adviser. Tang’s lab pioneered how to attach conjugated organic molecules to the silicon nanoparticles.

“This work is very fundamental,” said co-author Lorenzo Mangolini, an associate professor of mechanical engineering, whose group made the silicon nanocrystals. “The novelty is really how to get the two parts of this structure — the organic molecules and the quantum confined silicon nanocrystals — to work together. We are the first group to really put the two together.”

Co-author Sean Roberts, an assistant professor of chemistry at The University of Texas at Austin, used ultrafast lasers to investigate how energy is transferred in this hybrid structure, and determined the process is both amazingly fast and efficient.

“The challenge has been getting pairs of excited electrons out of these organic materials and into silicon. It can’t be done just by depositing one on top of the other,” said Roberts. “It takes building a new type of chemical interface between the silicon and this material to allow them to electronically communicate.”

The discovery could also lead to improved photocatalysis, which uses light to drive chemical reactions.

“Photocatalysts generally only work with ultraviolet light or violet light, so this is a way to generate that from the rest of the solar spectrum,” Tang said.

The environmentally sustainable silicon-centered approach is also relevant for quantum information science and singlet fission-driven solar cells.