Português

Scientists have demonstrated a new way to make infrared light from quantum dots, and the experiments are still in the early stages

860
2023-09-08 14:11:19
Ver tradução

Scientists at the University of Chicago have demonstrated a way to create infrared light using colloidal quantum dots. The researchers say this approach shows great promise; Although the experiment is still in its early stages, these quantum dots are already as efficient as existing conventional methods.

These points could one day form the basis of infrared lasers, as well as small and inexpensive sensors, such as those used in emissions tests or breathalyzers.

"Currently, the performance of these quantum dots is close to that of existing commercial infrared light sources, and we believe we can significantly improve this," says Philippe Guyot-Sionnest, co-author of the study published in Nature Photonics. One of the three authors on the paper.

Suitable wavelength

Colloidal quantum dots are tiny crystals - you could fit a billion crystals at the end of this sentence - and they will emit different colors of light, depending on how big you make them. They are highly efficient, easy to manufacture and are already used in commercial technology; You may have already bought a quantum dot TV and not know it.

However, these quantum dots are being used to make light at visible wavelengths - the part of the spectrum that humans can see. If you want quantum-dot light at infrared wavelengths, you're making a big mistake.

But infrared light has many uses. In particular, it's very useful for making sensors. For example, if you want to know if there are harmful gases in your car's exhaust, or test if you are breathing over the legal alcohol limit, or make sure there is no methane gas in your drilling equipment, you can use infrared. That's because different types of molecules absorb specific wavelengths of infrared light, so they're easy to tell apart.

Infrared lasers are now manufactured by a method called molecular epitaxy, which works well but requires a lot of labor and cost. Scientists think there may be another way.

Guyot-Sionnest and his team have been experimenting with quantum dots and infrared technology for years. Building on their previous invention, they set out to try to recreate a "cascade" technique that has been widely used to make lasers but has never been achieved on colloidal quantum dots.

In this "cascade" technique, researchers apply an electric current to the device, sending millions of electrons through the device. If the structure of the device is just right, the electrons will pass through a series of different energy levels, as if falling down a series of waterfalls. Every time an electron drops an energy level, it has a chance to release some of its energy in the form of light.

The researchers wondered if they could create the same effect with quantum dots. They created a black "ink" made up of trillions of tiny nanocrystals, spread it on a surface, and let an electric current pass through it.

"We thought it might work, but we were really surprised at how well it worked," Guyot-Sionnest said. "From our first attempt, we saw the light."

In fact, they found that this method is already as effective as other traditional methods of generating infrared light, even in exploratory experiments. The scientists say that with further improvements, the method could easily outperform existing methods.

Potential application

They hope the discovery will significantly reduce the cost of infrared light and lasers, opening up new applications.

"I think this is one of the best examples of the potential applications of quantum dots," Guyot-Sionnest said. "Many other applications can be achieved with other materials, but this structure really only works because of quantum mechanics." I think it's moving the field forward in a really interesting way."

Source: Chinese Optical Journal Network

Recomendações relacionadas
  • Overview of ultrafast laser micro nano manufacturing technology: material processing, surface/interface control, and device manufacturing

    Researchers from Tsinghua University have summarized the research on ultrafast laser micro nano manufacturing technology, including material processing, surface/interface control, and device manufacturing. The relevant review titled "A Review of Ultrafast Laser Micro/Nano Fabric: Material Processing, Surface/Interface Control, and Device Fabric" was published in Nano Research.Ultra fast laser proc...

    2024-08-06
    Ver tradução
  • Marvel Fusion received an additional € 50 million in Series B funding

    Recently, Marvel Fusion, which focuses on developing laser fusion energy systems, announced that the company has received an additional € 50 million in Series B funding. This latest investment is provided by EQT Venture Capital and Siemens Energy, and is also the first investment of the European Innovation Council (EIC) fund in fusion energy. In addition to the 63 million euros investment announce...

    04-08
    Ver tradução
  • The Asia Photonics Expo will be held in Singapore from February 26th to 28th, 2025

    The Asia Photonics Expo (APE), as an internationally leading comprehensive brand promotion and business negotiation platform for optoelectronics, will be grandly held from February 26 to 28, 2025 at the L1 exhibition hall of the Sands Expo&Convention Centre in Singapore. As the top event in the field of optoelectronics, APE Asia Optoelectronics Expo will focus on cutting-edge innovative techno...

    01-03
    Ver tradução
  • The output power of high power femtosecond laser breaking through the key bottleneck of average power can reach the order of 100 watts

    High energy, high average power femtosecond laser due to the attosecond high order harmonic generation, precision processing and manufacturing, biomedical and national defense and other fields of extensive application needs, is the forefront of ultrafast super laser technology research in the past decade.Especially fiber laser due to stable and reliable operation characteristics, compact structure...

    2023-09-04
    Ver tradução
  • Latest breakthrough! 3500W free output blue semiconductor laser

    The 3500W free output blue semiconductor laser beam is output in a free space manner, with a rectangular spot directly acting on the material surface without the need for fiber optics or laser processing heads. This laser has a wavelength of 455 ± 10nm, with continuously adjustable power and a maximum output power of over 3500W. It is mainly used for non-ferrous metal cladding, quenching, etc., to...

    2024-09-03
    Ver tradução