NRL Develops Technique To Speed Detection Process


2/12/2010 - 6-10r
Contact: Dom Panciarelli, (202) 767-2541


Researchers at the Naval Research Laboratory are developing a device to enable rapid detection and identification of bacteria, chemicals, and explosives in the environment or on the battlefield.

The new device, called the Swept Wavelength Optical resonant-Raman Device (SWOrRD), illuminates a sample with a sequence of as many as 100 laser wavelengths and measures the spectrum of light scattered from the sample at each laser wavelength. The assembly of scattered light-spectra constitutes a two-dimensional (2D) signature of the sample from which the components of the sample can be determined, with an appropriate algorithm. A code to perform an identification in near real-time is also being developed at NRL.

According to NRL's Dr. Jacob Grun, the research team leader, "When the laser wavelengths resonate with chemical bonds of the sample being examined, then light scattered at each wavelength contains additional information about the sample's identity. The 2D signature, rich in such information, helps to identify the sample's components even when a number of different chemicals or bacteria are mixed within that sample, as they normally would be in the environment or battlefield. This is much more difficult to do if only a single laser wavelength is used for illumination. SWOrRD also opens the possibility that a single detector can be used to identify biological agents as well as chemicals and explosives."

The new technique has both civilian and military applications. Potential uses include rapid screening in hospital, public health, food and water safety, decontamination, and border security applications. For military applications, the ability to quickly detect and identify multiple threats with a single device that has a minimal supply chain and that can be reprogrammed in the field to adjust to unexpected threats is crucial for protection of troops in the field. The technique also provides a test bed on which simpler devices suitable for large-scale deployment, utilizing few laser wavelengths, can be designed and evaluated.

During their studies, the NRL research team measured 2D spectra of five bacterial species and five explosives and showed the distinguishability of the signatures. The team was able to show that bacteria with similar RNA sequences were distinguishable by this method. The team then used the new technique to measure 2D signatures of potential environmental interferents, also with positive results.

The researchers are members of the NRL's Plasma Physics Division, the Remote Sensing Division, the Center for Bio/Molecular Science and Engineering, and Research Support Instruments Inc.; and are sponsored by the Defense Joint Science and Technology Office/Defense Threat Reduction Agency (JSTO/DTRA).


Spectral signatures of the military explosive, HMX, obtained by illumination with a single laser wavelength of 261nm (inset) and by illumination with many laser wavelengths ranging, from 210nm to 270nm. The multi-wavelength signature contains more information than the single-wavelength signature, which is useful when the chemical one is looking for is mixed with other chemicals that exist in battlefield or natural environments.



Get NRL News: RSS


About the U.S. Naval Research Laboratory

The U.S. Naval Research Laboratory is the Navy's full-spectrum corporate laboratory, conducting a broadly based multidisciplinary program of scientific research and advanced technological development. The Laboratory, with a total complement of approximately 2,500 personnel, is located in southwest Washington, D.C., with other major sites at the Stennis Space Center, Miss., and Monterey, Calif. NRL has served the Navy and the nation for over 90 years and continues to meet the complex technological challenges of today's world. For more information, visit the NRL homepage or join the conversation on Twitter, Facebook, and YouTube.

Comment policy: We hope to receive submissions from all viewpoints, but we ask that all participants agree to the Department of Defense Social Media User Agreement. All comments are reviewed before being posted.