简体中文

Scientists propose new methods to accelerate the commercialization of superlens technology

846
2024-03-29 14:51:52
查看翻译

Superlenses are nano artificial structures that can manipulate light, providing a technique that can significantly reduce the size and thickness of traditional optical components. This technology is particularly effective in the near infrared region, and has great prospects in various applications, such as LiDAR, which is called "the eye of autonomous vehicle", mini UAV and blood vessel detector.

Despite its potential, current technology requires tens of millions of Korean won to manufacture nail sized superlenses, which poses a challenge to commercialization. Fortunately, a recent breakthrough indicates that its production costs are expected to decrease by one thousandth in price.

A collaborative research team composed of Professor Junsuk Rho from the Department of Mechanical Engineering and the Department of Chemical Engineering at Pohang University of Science and Technology has proposed two innovative methods for large-scale production of superlenses and manufacturing them on large surfaces. Their research is published in the Review of Laser and Photonics.

Lithography is a process of manufacturing a superlens by printing patterns on a silicon wafer using light. Usually, the resolution of light is inversely proportional to its wavelength, which means that shorter wavelengths lead to higher resolution, allowing for the creation of finer and more detailed structures. In this study, the team chose deep ultraviolet lithography technology, which is a process that uses shorter wavelengths of ultraviolet light.
The research team recently achieved large-scale production of visible light region superlenses using deep ultraviolet lithography technology, which was published in the journal Nature Materials. However, due to the low efficiency of existing methods in the infrared region, challenges have arisen.

To address this limitation, the team developed a material with high refractive index and low infrared region loss. This material was integrated into the established large-scale production process, resulting in the successful manufacture of a relatively large infrared superlens with a diameter of 1 centimeter on an 8-inch wafer.

It is worth noting that this lens has an excellent numerical aperture of 0.53, highlighting its excellent light gathering ability and high resolution close to the diffraction limit. The cylindrical structure further ensures excellent performance without being affected by polarization, regardless of the direction of light vibration.

In the second method, the team employed nanoimprinting, a process that allows for the use of molds to print nanostructures. This process utilizes the knowledge of nanoimprinting technology accumulated through collaborative research with RIT.

This effort has been proven successful as the team managed to mass produce a 5-millimeter diameter superlens composed of approximately 100 million rectangular nanostructures on a 4-inch wafer. It is worth noting that this type of superlens exhibits impressive performance, with an aperture of 0.53. Its rectangular structure exhibits polarization dependence and can effectively respond to the direction of light vibration.

On the basis of this achievement, the team integrated a high-resolution imaging system to observe real samples such as onion skins, verifying the possibility of commercializing superlenses.

This study is of great significance as it overcomes the limitations of traditional individual production processes for superlenses. It not only helps to create optical devices with polarization dependence and independent characteristics, tailored for specific applications, but also reduces the production cost of superlenses by up to 1000 times.
Professor Junsuk Rho said, "We have achieved precise and rapid production of wafer level high-performance superlenses, reaching the centimeter level. Our goal is to accelerate the industrialization of superlenses and promote the advancement of efficient optical devices and optical technology through this research.".

Source: Laser Net

相关推荐
  • The "white" laser device from startup Superlight Photonics will completely transform imaging

    Superlight Photonics, a start-up company headquartered in Enshurd, has developed a broadband laser chip that can replace the bulky and power consuming technology currently used in advanced imaging and metering equipment.This idea suddenly appeared in his mind, while moving his other belongings from Germany to his new home in Enschede. During his doctoral research at the Max Planck Institute of Mul...

    2023-10-28
    查看翻译
  • Shanghai Optics and Machinery Institute has made progress in femtosecond fiber lasers based on twisted Sagnac interferometer mode locking

    Recently, the research team of the Aerospace Laser Technology and System Department of the Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, proposed a torsional Sagnac interferometer and applied it to the fiber laser system, realizing mode locking self starting and pulse shaping. The relevant research achievements were published in the Journal of Lightwave Technology u...

    2024-04-22
    查看翻译
  • 2Pi Optics has launched a new type of fisheye camera based on its so-called metasurface optics

    2Pi Optics has launched a new type of fisheye camera based on its so-called metasurface optics.The company plans to showcase this technology at the large-scale technology trade show CES 2024 in Las Vegas next week.This company, headquartered in Cambridge, Massachusetts, stated that it has created the world's leading high-resolution fisheye sensor based on optical superlens technology. This technol...

    2024-01-05
    查看翻译
  • The company has made key breakthroughs in the development of laser micromachining systems

    3D-Micromac AG, a provider of laser micromachining systems, has announced new advances in laser micromachining solutions for magnetic sensors, micro-leds, manufactured power devices and advanced packaging of semiconductors.Since the first working laser came out more than 60 years ago, lasers have been widely used in the industrial market. Uwe Wagner, CEO of 3D-Mircomac, said: "In the semic...

    2023-08-04
    查看翻译
  • The latest progress in laser chip manufacturing

    Modern computer chips can construct nanoscale structures. So far, only these tiny structures can be formed on top of silicon chips, but now a new technology can create nanoscale structures in a layer beneath the surface. The inventor of this method stated that it has broad application prospects in the fields of photonics and electronics, and one day, people can manufacture 3D structures on the ent...

    2024-07-29
    查看翻译