First ever produced
Prototype asbestos detector with the lid removed. The detectors are undergoing trials at various locations where asbestos removal operations are underway. Image: Paul Kaye, Univ. of Hertfordshire, UK
June 30, 2013 — Asbestos was once called a miracle material because of its toughness and fire-resistant properties. It was used as insulation, incorporated into cement and even woven into firemen's protective clothing. Over time, however, scientists pinned the cause of lung cancers such as mesothelioma on asbestos fiber inhalation. Asbestos was banned in many industrialized countries in the 1980s, but the threat lingers on in the ceilings, walls and floors of old buildings and homes.
Now a team of researchers from the University of Hertfordshire in the U.K. has developed and tested the first portable, real-time airborne asbestos detector. They expect the detector described in a paper published in the Optical Society's (OSA) open-access journal Optics Express, to be commercialized in the next few years, providing roofers, plumbers, electricians and other workers in commercial and residential buildings with an affordable way to quickly identify if they have inadvertently disturbed asbestos fibers into the air.
"Many thousands of people around the world have died from asbestos fiber inhalation," says Paul Kaye, a member of the team that developed the new detection method at the University of Hertfordshire's School of Physics, Astronomy and Mathematics. "Even today, long after asbestos use was banned in most Western countries, there are many people who become exposed to asbestos that was used in buildings decades earlier, and these people too are dying from that exposure."
Currently, the most common way to identify hazardous airborne asbestos at worksites is to filter the air, count the number of fibers that are caught, and later analyze the fibers with X-ray technology to determine if they are asbestos. The approach requires expensive lab work and hours of wait time. An alternative method to evaluate work site safety is to use a real-time fiber detector, but the current, commercially available detectors are unable to distinguish between asbestos and other less dangerous fibers such as mineral wool, gypsum and glass. The University of Hertfordshire team's new detection method, in contrast, can identify asbestos on-site. It does so by employing a laser-based technique that takes advantage of a unique magnetic property of the mineral.
When exposed to a magnetic field, asbestos fibers orient themselves to align with the field. The property is virtually unique among fibrous materials. "Asbestos has a complex crystalline structure containing several metals including silicon, magnesium and iron. It is thought that it is the iron atoms that give rise to the magnetic properties, but the exact mechanism is still somewhat unclear," says Kaye.
The Hertfordshire team's new detection method works by first shining a laser beam into a stream of airborne particles. When light bounces off the particles, it scatters to form unique, complex patterns. The pattern "is a bit like a thumbprint for the particle," says Kaye, making it possible to identify a its shape, size, structure. "We can use this technique of light scattering to detect single airborne fibers that are far too small to be seen with the naked eye," he says. After identifying the fibers, the detector carries them in an airflow through a magnetic field, and uses light scattering again on the other side to tell if the fibers have aligned with the field. "If they have, they are highly likely to be asbestos."
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