Compact Chemical Sensor Can Detect Substances from Over 100 Feet Away
News Jan 17, 2018 | Original Story by Ann Arbor for the University of Michigan.
Credit: the University of Michigan.
A chemical sensor prototype developed at the University of Michigan will be able to detect "single-fingerprint quantities" of substances from a distance of more than 100 feet away, and its developers are working to shrink it to the size of a shoebox.
It could potentially be used to identify traces of drugs and explosives, as well as speeding the analysis of certain medical samples. A portable infrared chemical sensor could be mounted on a drone or carried by users such as doctors, police, border officials and soldiers.
The sensor is made possible by a new optical-fiber-based laser that combines high power with a beam that covers a broad band of infrared frequencies—from 1.6 to 12 microns, which covers the so-called mid-wave and long-wave infrared.
"Most chemicals have fingerprint signatures between about 2 and 11 microns," said U-M researcher Mohammed Islam, who developed the laser. "Hence, this wavelength range is called the 'spectral fingerprint region.' So our device enables identification of solid, liquid and gas targets based on their chemical signature."
The project is a collaboration among U-M, global technology company Leidos, fiber makers IRflex and CorActive and U-M startup Omni Sciences, which was founded by Islam. The project is funded by the U.S. Intelligence Advanced Research Projects Activity.
Islam, U-M professor of electrical and computer engineering and biomedical engineering, and his team built their device with off-the-shelf fiber optics and telecommunications components, save one custom-made optical fiber. This approach ensures that the laser will be reliable and practical to manufacture at a reasonable cost.
"We've shown we can make a $10,000 laser that can do everything a $60,000 laser can do," Islam said.
Broadband infrared lasers are typically built up from a laser that produces very short pulses of light, and then a series of amplifiers ramps up the power, but this approach is limited to laboratories. In addition to their high costs, these components can't yet shrink small enough to fit into a handheld device. Plus, the use of lenses and mirrors would make the device sensitive to jostling and changes in temperature.
To craft their new laser, the team started with a standard laser diode, similar to those in laser pointers and barcode scanners. This pulse was then boosted in power with telecom amplifiers—similar to those used in the field to periodically ramp voice signals backup as they diminish over long travels through the fiber-optic lines. Then they ran this powerful, broadband signal through a 2-meter coil of optical fiber.
"This is where the magic comes in," said Islam. "We put in these roughly one-nanosecond pulses at this high power and they break up into very narrow series of small short pulses, typically less than a picosecond in width. So basically for the price of 20 cents of fiber, we obtain the same kind of output as very expensive mode-locked lasers."
Then, in a process known as "supercontinuum generation," they expanded the wavelengths covered by that light by sending it through specialized softer glass fibers. Most lasers emit light of just one wavelength, or color. But supercontinuum lasers give off a focused beam packed with light from a much broader range of wavelengths.
Visible-wavelength supercontinuum lasers, for example, discharge tight columns that appear white because they contain light from across the visible spectrum. Islam's broadband infrared supercontinuum laser does the equivalent, but in longer infrared wavelengths.
To use the device, the researchers shine the laser on an object and analyze the reflected light to identify what wavelengths did not bounce back. They can identify chemicals by the unique pattern of infrared wavelengths that they absorb.
The team successfully demonstrated the laser for the U.S. Intelligence Advanced Research Projects Activity in August 2017, analyzing 70 mystery samples over two days of testing. Phase 2 of the project will entail shrinking the system toward the size of a shoebox, a process that will be led by Leidos and Omni Sciences.
In addition to the applications in policing and defense, Islam sees a future for the technology in medicine. For instance, tissue samples are chemically analyzed in a laboratory—a process that takes time and materials. Islam thinks the laser could provide an assessment of the chemical content on the spot. It may even be possible to run the beam through a scope and analyze tissue right in the body.
This article has been republished from materials provided by the University of Michigan. Note: material may have been edited for length and content. For further information, please contact the cited source.
Mid-infrared supercontinuum generation from 1.6 to >11 μm using concatenated step-index fluoride and chalcogenide fibers. Ramon A. Martinez, Genevieve Plant, Kaiwen Guo, Brian Janiszewski, Michael J. Freeman, Robert L. Maynard, Mohammed N. Islam, Fred L. Terry, Oseas Alvarez, Francois Chenard, Robert Bedford, Ricky Gibson, and Agustin I. Ifarraguerri. Optics Letters Vol. 43, Issue 2, pp. 296-299 (2018) •https://doi.org/10.1364/OL.43.000296.
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