Français

Breaking the limits of optical imaging by processing trillions of frames per second

793
2024-04-08 15:40:00
Voir la traduction

Pursuing higher speed is not just exclusive to athletes. Researchers can also achieve such feats through their findings. The research results of Professor Liang Jinyang and his team from the National Institute of Science (INRS) have recently been published in the journal Nature Communications.

The team located at the INRS É nergie Mat é riaux T é l é communications research center has developed a new type of ultrafast camera system that can capture up to 156.3 trillion frames per second with astonishing accuracy. For the first time, a single ultra fast demagnetization of two-dimensional optical imaging has been achieved. This new device called SCARF (Scanning Aperture Real Time Femtosecond Photography) can capture transient absorption in semiconductors and ultrafast demagnetization of metal alloys. This new method will help advance the knowledge frontier in a wide range of fields such as modern physics, biology, chemistry, materials science, and engineering.

Professor Liang is renowned as a pioneer in the field of ultrafast imaging. In 2018, as a major developer, he made significant breakthroughs in this field, laying the foundation for the development of SCARF.

So far, ultrafast camera systems mainly use a frame by frame sequential capture method. They will obtain data through brief and repeated measurements, and then combine all the content to create a movie that reconstructs the observed motion.

Professor Liang Jinyang said, "However, this method can only be applied to inert samples or phenomena that occur in exactly the same way every time. Fragile samples, let alone non repeatable or ultrafast phenomena, cannot be observed with this method."

"For example, phenomena such as femtosecond laser ablation, interaction between shock waves and live cells, and optical chaos cannot be studied in this way," explained Liang Jinyang.

The first tool developed by Professor Liang helped fill this gap. The T-CUP (trillion frames per second compressed ultrafast photography) system is based on passive femtosecond imaging and can capture billions (1013) of frames per second. This is an important first step towards ultrafast, single shot real-time imaging.

SCARF has overcome these challenges. Its imaging method can scan the static coding aperture ultra fast without cutting the ultra fast phenomenon. This can provide a full sequence encoding rate of up to 156.3 THz for each pixel on cameras with charge coupled devices (CCD). These results can be obtained in both reflection and transmission modes at adjustable frame rates and spatial scales in a single attempt.

SCARF makes it possible to observe unique phenomena that are ultrafast, non repeatable, or difficult to reproduce, such as shock wave mechanics in living cells or substances. These advances may be used to develop better drugs and medical methods.

More importantly, SCARF promises to bring very attractive economic byproducts. Axis Photonique and Few Cycle have collaborated with Professor Liang's team to produce a saleable version of their patent pending discovery. This is an excellent opportunity for Quebec to consolidate its enviable position as a leader in photonics.

Source: Laser Net

Recommandations associées
  • The Glory of Laser and the Odyssey of "Deep Technology"

    The British engineering and construction company Metz Group has a delegation in Spain to be responsible for the expansion and renovation of the central laser facility at Rutherford Appleton Laboratory near Oxford. More commonly, the construction of the powerful laser Vulcan 20-20 has just been obtained, with a delivery date of 2029.It will emit a main excitation beam that is billions of times larg...

    2023-12-09
    Voir la traduction
  • New progress in research on laser cleaning and improving the damage threshold of fused quartz components at Shanghai Optics and Machinery Institute

    Recently, the research team of the High Power Laser Element Technology and Engineering Department of the Shanghai Institute of Optics and Mechanics, Chinese Academy of Sciences, has made new progress in the study of improving the damage threshold of fused quartz elements through laser cleaning. The study proposes for the first time the use of microsecond pulse CO2 laser cleaning to enhance the dam...

    2024-07-08
    Voir la traduction
  • Laser communication is expected to completely change optical links

    Laser technology is becoming a game changer in the field of satellite communication (SATCOM), capable of creating ultra secure networks that can transmit large amounts of data at unprecedented speeds through satellite networks and constellations.With continuous progress, the industry is ready for growth and collaboration, seizing the untapped potential of disconnected populations. The ability to h...

    2023-09-20
    Voir la traduction
  • Intelligent laser welding with dynamic beam shaping function can reduce the demand for filler wire

    In EU project ALBATROSS, Fraunhofer IWS has developed battery housing for E-vehicles.Laser processes with dynamic beam shaping create stable joints even in challenging material combinations. Recent applications demonstrate how to eliminate filler materials while improving quality, energy efficiency, and production logic.Fraunhofer Institute for Material and Beam Technology (IWS) will present novel...

    09-05
    Voir la traduction
  • 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
    Voir la traduction