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Simple method can recover and recycle quantum dots in microscopic lasers

Researchers develop technique to recover and recycle quantum dots in microscopic lasers
The unified process of SP fabrication and recycling; 1. CQD precipitation, 2. Self-assembly, 3. Completed fabrication of SPs, 4. Sonication & heat treatments, 5. Separation & filtration, 6. Ligand re-attachment, 7. Recovery of CQDs. Credit: Optical Materials Express (2024). DOI: 10.1364/OME.537183

Researchers have discovered a way to recycle the tiny particles used to create supraparticle lasers, a technology that precisely controls light at a very small scale. The breakthrough could help manage these valuable materials in a more sustainable way.

Supraparticle lasers work by trapping light inside a tiny sphere made of special particles called quantum dots, which can absorb, emit, and amplify light very efficiently.

They are made by mixing quantum dots in a solution that helps them stick together in tiny bubbles. However, not all attempts succeed, and even successful lasers degrade over time. This leads to wasted materials, which can be expensive.

Recycling method

The idea to recycle these particles came up during a team discussion about the high cost of wasted quantum dots. Dillon Downie, a Ph.D. student in the Institute of Photonics at the University of Strathclyde, suggested a potential solution, and with the support of team leader Dr. Nicolas Laurand, they tested the idea. To their surprise, they were able to recover and reuse the particles to make new lasers.

Dillon said, "Supraparticle lasers are already beginning to be used for targeted and sensing applications, as well as for components in compact electronic systems. Nanoparticle aggregates and supraparticle lasers are expected to play an increasingly prominent role in everything from wearable medical devices to ultrabright LEDs.

"Our recycling method reduces costs and environmental impact by minimizing the need for new nanoparticles and the disposal of old ones, and it should be applicable to any colloidal nanoparticle species, especially rare-earth ones."

In a paper titled "Recycling self-assembled colloidal quantum dot supraparticle lasers," published in the journal Optical Materials Express, the Strathclyde researchers describe how they recycled quantum dots from used lasers to make new ones that work just as well as the originals.

Dillon said, "We envision this method being used to extend the life cycle of supraparticles, which could be repurposed for various applications such as medical biosensors, representing a significant advance toward sustainable nanoengineering."

Simple method

The starts by breaking apart the used lasers by heating the particles and exposing them to sound waves. The quantum dots were then separated from impurities using a mix of oil and water, followed by filtering and coating the particles to restore their properties. Finally, the research team tested the recycled dots to ensure they could still emit light effectively and used them to create new lasers.

This method recovered 85% of the original quantum dots, which still performed almost as well as new ones. The recycled dots were then used to make lasers that worked just like the originals.

The team plans to study how recycling affects the performance of the over time and to develop ways to recycle more complex or specialized particles.

Dillon added, "Our simple method doesn't need fancy equipment, so it can be used in most labs. This is a big step toward making more sustainable."

More information: Dillon H. Downie et al, Recycling self-assembled colloidal quantum dot supraparticle lasers, Optical Materials Express (2024). DOI: 10.1364/OME.537183

Journal information: Optical Materials Express

Citation: Simple method can recover and recycle quantum dots in microscopic lasers (2024, November 26) retrieved 4 December 2024 from https://phys.org/news/2024-11-simple-method-recover-recycle-quantum.html
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