Español

The Science Island team has made new progress in detecting atmospheric formaldehyde

844
2023-09-21 14:34:23
Ver traducción

Recently, Zhang Weijun, a research team of the Anguang Institute of the Chinese Academy of Sciences, Hefei Academy of Materials, made new progress in atmospheric formaldehyde detection, and the related achievements were published on the international TOP journal Sensors and Actors: B. Chemical under the title of "Portable highly sensitive laser absorption spectrum formaldehyde sensor based on compact spherical mirror optical multi-path cell".

Formaldehyde is an important atmospheric pollutant, mainly originating from industrial processes, chemical products, and motor vehicle emissions. In atmospheric chemistry, formaldehyde is a key intermediate product in the oxidative degradation process of volatile organic compounds (VOCs) emitted by humans and nature; In indoor environments, excessive formaldehyde levels are an important cause of cancer, especially leukemia. Therefore, real-time monitoring of atmospheric formaldehyde is of great significance for the study of atmospheric pollution chemistry and health effects.

In 2019, researcher Zhao Weixiong and assistant researcher Fang Bo from An Guang Institute team developed a TDLAS device for actual atmospheric formaldehyde measurement using a long path new spherical mirror cell combined with mid infrared tunable laser absorption spectroscopy (TDLAS) technology. They also participated in field observations in the Guangdong Hong Kong Macao Greater Bay Area and other areas.

Based on this research, a compact optical multi-pass cell with high optical path to volume ratio (optical path 50.6 m, volume~350 mL) was developed to meet the miniaturization, fast response, and high sensitivity development needs of TDLAS formaldehyde measurement devices. Its gas displacement response time is less than 1 second. Combined with fast background subtraction technology, this device can obtain 650 pptv in 1 second of integration time( α Min~2.3 × Detection limit of 10-9 cm-1). This research work laid the foundation for the team to further develop portable handheld/vehicle formaldehyde detection equipment.

This work has been supported by the National Natural Science Foundation of China, the Youth Innovation Promotion Association of the Chinese Academy of Sciences, and the President's Fund of Hefei Research Institute.

Compact spherical mirror optical multi pass cell with high optical path volume ratio


Structure diagram of formaldehyde detection device


Fast background subtraction and detection limit


Source: Hefei Institute of Physical Sciences, Chinese Academy of Sciences

Recomendaciones relacionadas
  • RTX Raytheon Company will develop ultra wide bandgap semiconductors for ultraviolet lasers

    The UWBGS program will develop and optimize ultra wide bandgap materials and manufacturing processes for the next revolution in the semiconductor electronics field.US military researchers need to develop new integrated circuit substrates, device layers, junctions, and low resistance electrical contacts for the new generation of ultra wide bandgap semiconductors. They found a solution from RTX comp...

    2024-09-30
    Ver traducción
  • NICT Japan corrects sudden data errors caused by atmospheric turbulence in laser links

    The National Institute of Information and Communication Technology of Japan, Nagoya Institute of Technology, and Japan Aerospace Exploration Agency have achieved the so-called "world's first successful demonstration of next-generation error correction codes, reducing the impact of atmospheric turbulence on ground to satellite laser communication".Atmospheric turbulence in ground-to-satellite laser...

    10-25
    Ver traducción
  • NUBURU Announces Second Next Generation Blue Laser Space Technology Contract with NASA

    NUBURU, the leading innovator of high-power and high brightness industrial blue laser technology, announced today that it has been awarded a second phase contract worth $850000 by the National Aeronautics and Space Administration (NASA) to advance blue laser power transmission technology as a unique solution that significantly reduces the size and weight of equipment required for lunar and Martian...

    2024-05-13
    Ver traducción
  • Microscopic Marvel photon devices have the potential to completely change the way physics and lasers are processed

    Researchers at Rensselaer Institute of Technology have developed a device that operates at room temperature, which is the first topological quantum simulator to operate under strong light matter interaction mechanisms, making high-tech research easier in cutting-edge ways.Researchers at Rensselaer Institute of Technology have developed a device no larger than human hair, which will enable physicis...

    2024-06-04
    Ver traducción
  • Jena Helmholtz Institute Using Air Deflection Laser Beam

    A novel method is used to deflect the laser beam using only air. The interdisciplinary research team reported in the journal Nature Photonics that invisible gratings made solely of air not only do not suffer damage from lasers, but also retain the original quality of the beam. The researchers have applied for a patent for their method.Technology and PrinciplesThis innovative technology utilizes so...

    2023-10-07
    Ver traducción