Technology developed by the National Physical Laboratory (Teddington, Middlesex, UK) (NPL) could help reverse the estimated $5.42 billion lost each year through the production of counterfeit clothing.
Technology developed by the National Physical Laboratory (Teddington, Middlesex, UK) (NPL) could help reverse the estimated $5.42 billion lost each year through the production of counterfeit clothing.
The new technique - based on terahertz time-domain spectroscopy - will help customs officers ascertain whether items of clothing are fake, assisting them in the seizure and destruction of fake goods.
The technique, described in an article titled “Terahertz Time-Domain Spectroscopy for Textile Identification,” in Applied Optics, requires the generation of a beam of terahertz radiation, which is a band of electromagnetic radiation that falls between microwaves and infrared light. A sample of fabric is then placed within this beam and the properties of the terahertz waves are detected after passing through the fabric.
The composition and structure of the different types of fabric give rise to different rates of beam scattering and absorption. Different fabrics posses a distinct transmission profile, which gives it a signature that indicates whether or not the fabric in question is counterfeit.
According to a statement, the research examined fabrics made from wool, cotton, linen, silk and mixed fibers, all of which demonstrated distinct terahertz transmission properties.
The technique could distinguish between fabrics that looked and felt similar but that had different compositions. It could, for example, tell the difference between plain wool and the more expensive merino wool, as well as between natural and synthetic silk.
The next stage will be to test batches of the same type of fabric from the same manufacturer in a potential collaboration. It is also necessary to create a database of the terahertz transmission properties of many different fabrics and to study further the relationship between these and the properties of the fabrics themselves.
The research was carried out in collaboration with the Institute of Monitoring of Climatic and Ecological Systems in Russia.
Getting accurate IR spectra on monolayer of molecules
April 18th 2024Creating uniform and repeatable monolayers is incredibly important for both scientific pursuits as well as the manufacturing of products in semiconductor, biotechnology, and. other industries. However, measuring monolayers and functionalized surfaces directly is. difficult, and many rely on a variety of characterization techniques that when used together can provide some degree of confidence. By combining non-contact atomic force microscopy (AFM) and IR spectroscopy, IR PiFM provides sensitive and accurate analysis of sub-monolayer of molecules without the concern of tip-sample cross contamination. Dr. Sung Park, Molecular Vista, joined Spectroscopy to provide insights on how IR PiFM can acquire IR signature of monolayer films due to its unique implementation.
Researchers Develop Adaptive Gap-Tunable SERS Device
April 24th 2024In a new study, researchers from Ulsan National Institute of Science and Technology and Pohang University of Science and Technology presented a new surface-enhanced Raman spectroscopy (SERS) device, improving gap plasmon resonance.