A new, onion-like nanoparticle’s innovation lies in its layers: a coating of organic dye, a neodymium-containing shell, and a core that incorporates ytterbium and thulium.
Together, these layers convert invisible near-infrared light to higher energy blue and UV light with record-high efficiency.
When it comes to bioimaging, near-infrared light could be used to activate the light-emitting nanoparticles deep inside the body, providing high-contrast images of areas of interest.
In the realm of security, nanoparticle-infused inks could be incorporated into currency designs. This kind of ink would be invisible to the naked eye, but glow blue when hit by a low-energy laser pulse— a trait very difficult for counterfeiters to reproduce.
Artist’s rendering shows the layers of the onion-like nanoparticle. (Credit: Kaiheng Wei)
“By creating special layers that help transfer energy efficiently from the surface of the particle to the core, which emits blue and UV light, our design helps overcome some of the long-standing obstacles that previous technologies faced.”
“Our particle is about 100 times more efficient at ‘upconverting’ light than similar nanoparticles created in the past, making it much more practical,” says Jossana Damasco, a chemistry PhD student who played a key role in the project.
Three Key Layers
Converting low-energy light to light of higher energies isn’t easy to do. The process involves capturing two or more tiny packets of light called photons from a low-energy light source, and combining their energy to form a single, higher-energy photon. The onionesque nanoparticle performs this task well.
Each of the nanoparticle’s three layers fulfills a unique function:
A transmission electron microscopy image. Each particle is about 50 nanometers in diameter. (Credit: Institute for Lasers, Photonics and Biophotonics/U. Buffalo)
The outermost layer is a coating of organic dye. This dye is adept at absorbing photons from low-energy near-infrared light sources. It acts as an “antenna” for the nanoparticle by harvesting light and transferring energy inside, says Ohulchansky.
The next layer is a neodymium-containing shell. This layer acts as a bridge, transferring energy from the dye to the particle’s light-emitting core.
Inside the light-emitting core, ytterbium and thulium ions work in concert. The ytterbium ions draw energy into the core and pass the energy on to the thulium ions, which have special properties that enable them to absorb the energy of three, four, or five photons at once, and then emit a single higher-energy photon of blue and UV light.
A Staircase for Energy
So why not just use the core? Why add the dye and neodymium layer at all?
As Ohulchanskyy and Chen explain, the core itself is inefficient in absorbing photons from the outside world. That’s where the dye comes in.
Once you add the dye, the neodymium-containing layer is necessary for transferring energy efficiently from dye to core.
Ohulchanskyy uses the analogy of a staircase to explain why this is: When molecules or ions in a material absorb a photon, they enter an “excited” state from which they can transfer energy to other molecules or ions.
The most efficient transfer occurs between molecules or ions whose excited states require a similar amount of energy to obtain, but the dye and ytterbium ions have excited states with very different energies.
So the team added neodymium—whose excited state is in between that of the dye and thulium’s—to act as a bridge between the two, creating a “staircase” for the energy to travel down to reach emitting thulium ions.