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Inspired by a chameleon’s prowess, researchers have made a tiny elastic laser that changes color as it is stretched and released (Nano Lett. 2018, DOI: 10.1021/acs.nanolett.8b01774). The tunable nanolaser system could be used in flexible displays, wearable sensors, and lab-on-a-chip devices.
Chameleon skin has a layer of cells containing guanine nanocrystals. When the lizard tenses or relaxes its skin, the space between the crystals changes, altering the color of reflected light. In the quest to make compact light sources with tunable colors, some researchers have tried to emulate this mechanism.
One design involves embedding regular arrays of semiconductor nanostructures inside a rubbery material. In these nanolasers, light shined on the devices bounces around between the nanostructures, gets amplified, and emerges as a laser beam of a defined wavelength. That color changes when the material is stretched, changing the spacing of the array.
By adding some twists to that concept, Teri W. Odom, George C. Schatz, and their colleagues at Northwestern University have made a tunable nanolaser that is 10 times as sensitive as previous stretchable nanolasers and has the potential to give a wider range of colors.
First, they deposited an array of cylindrical, 260-nm-wide gold nanoparticles on a polydimethylsiloxane sheet. They surrounded the nanoparticles with a liquid gain material, a dye solution that amplifies light to achieve lasing. In previous work, Odom and colleagues had made a tunable nanolaser with a liquid gain material, but to change the nanolaser’s color, they had to switch out the dye solution.
In this new design, stretching does the trick instead. When activated with an external light source, the nanolaser emits near-infrared light at around 870 nm. The wavelength increases, or shifts farther into the infrared, when the device is stretched and goes back to the original wavelength when released.
“A liquid gain medium is perfect for a stretchable device,” Odom says. “When you stretch the substrate, the liquid follows it perfectly so there are always molecules to amplify light for lasing.”
The other novelty of the device is that it harnesses plasmons—collective oscillations of electrons—that exist on the surface of gold nanoparticles. “The plasmonic nanoparticles act like little antennas that concentrate incoming light into electromagnetic fields right around their surface,” Odom says.
So the surfaces become nanoscopic hotspots for lasing, and the tiniest change in the spacing between the nanoparticles causes a measurable color shift, making the device very sensitive. It gives slightly more wavelength change with only one-tenth of the stretching required for earlier similar laser designs.
Plus, tweaking both the type of dye and the nanoparticle spacing could give a wide range of emitted laser light colors, Odom says. The researchers now plan to make a device with a mixed nanoparticle array of different plasmonic materials, along with gold. Silver and aluminum nanoparticles, for instance, emit light in ultraviolet and visible wavelengths. “Side by side on the same substrate, you can imagine getting different [visible] lasing colors,” Odom says.
The combination of changeable liquid material and the plasmon resonance gives a robust, high-performance, and compact laser with wide-range tunability, says Ren-Min Ma, a physicist at Peking University. “It is a significant step towards the implementation of functional nanolasers.”
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