This image shows the process for achieving superfluorescence with UCNPs at room temperature. Image: Shuang Fang Lim, NC State University.
This image shows the process for achieving superfluorescence with UCNPs at room temperature. Image: Shuang Fang Lim, NC State University.

Researchers looking to synthesize a brighter and more stable nanoparticle for optical applications found that their creation instead exhibited a more surprising property: bursts of superfluorescence that occurred at both room temperature and at regular intervals. This work, reported in a paper in Nature Photonics, could lead to the development of faster microchips, neurosensors, and materials for use in quantum computing and biological studies.

Superfluorescence occurs when atoms within a material synchronize and simultaneously emit a short but intense burst of light. The property is valuable for quantum optical applications, but extremely difficult to achieve at room temperatures and for intervals long enough to be useful.

The nanomaterial in question – lanthanide-doped upconversion nanoparticle (UCNP) – was synthesized by the research team in an effort to create a ‘brighter’ optical material. They produced hexagonal ceramic crystals ranging from 50nm to 500nm in size and began testing their lasing properties, which resulted in several impressive breakthroughs.

The researchers were initially looking for lasing, where light emitted from one atom stimulates another to emit more of the same light. However, they instead found superfluorescence, where first all the atoms align, then emit light together.

“When we excited the material at different laser intensities, we found that it emits three pulses of superfluorescence at regular intervals for each excitation,” says Shuang Fang Lim, associate professor of physics at North Carolina State University and co-corresponding author of the paper. “And the pulses don’t degrade – each pulse is two nanoseconds long. So not only does the UCNP exhibit superfluorescence at room temperatures, it does so in a way that can be controlled.”

Room-temperature superfluorescence is hard to achieve because it is difficult for atoms to emit light together without being ‘kicked’ out of alignment by their surroundings. In a UCNP, however, the light comes from electron orbitals ‘buried’ beneath other electrons, which act as a shield and allow superfluorescence even at room temperature.

Additionally, the UCNP’s superfluorescence is technologically exciting because it is anti-Stokes shifted, meaning that the emitted wavelengths of light are shorter and higher energy than the wavelengths that initiate the response.

“Such intense and rapid anti-Stokes-shift superfluorescence emissions are perfect for numerous pioneering materials and nanomedicine platforms,” says Gang Han, professor of biochemistry and molecular biotechnology at the University of Massachusetts Chan Medical School and co-corresponding author of the paper. “For example, the UCNPs have been widely used in biological applications ranging from background-noise-free biosensing, precision nanomedicine and deep-tissue imaging, to cell biology, visual physiology and optogenetics.

“However, one challenge to current UCNP applications is their slow emission, which often makes detection complex and suboptimal. But the speed of anti-Stokes-shift superfluoresence is a complete game changer: 10,000 times faster than the current method. We believe that this superfluorescence nanoparticle provides a revolutionary solution to bioimaging and phototherapies that await a clean, rapid and intensive light source.”

The unique qualities of UCNPs could lead to their use in numerous applications. “First, room temperature operation makes applications much easier,” Lim says. “And at 50nm, this is the smallest superfluorescent media currently in existence. Since we can control the pulses, we could use these crystals as timers, neurosensors or transistors on microchips, for example. And bigger crystals could give us even better control over the pulses.”

This story is adapted from material from North Carolina State University, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.