NRL Scientists Elevate Warfighter Readiness Against Invisible Threats


2/10/2011 - 13-11r
Contact: Daniel Parry, (202) 767-2541


In asymmetric warfare, early detection and identification of trace level chemical and biological agents and explosive compounds is critical to rapid reaction, response, and survivability. While there are many methods currently being used that can detect these threats, none allow for the unique fingerprinting of threat agents at trace levels.

Scientists Orest Glembocki (holding a DeltaNu ExamineR hand-held Raman spectrometer) and Joshua Caldwell, display one of the silicon wafers they fabricated for the SERS sensing using ion etching and e-beam lithography. Several square arrays of gold-coated silicon nanopillar were fabricated on the wafer to perform surface-enhanced Raman scattering testing.

A research team, led by Drs. Joshua Caldwell and Orest Glembocki, scientists at the U.S. Naval Research Laboratory, in collaboration with Drs. Sharka Prokes and Ronald Rendell, NRL Electronic Science and Technology Division, has overcome this limitation with surface enhanced Raman scattering (SERS) using optically stimulated plasmon oscillations in nanostructured substrates.

Shown to provide enhancements of the Raman signal, large-area gold (Au) coated silicon (Si) nanopillar arrays are over 100 million times (108) more sensitive than Raman scattering sensing alone, while maintaining a very uniform response with less than 30 percent variability across the sensor area.

"These arrays are over an order-of-magnitude more sensitive than the best reported SERS sensors in the literature and the current state-of-the-art large-area commercial SERS sensors," said Caldwell. "These arrays can be a key component of fully integrated, autonomously operating chemical sensors that detect, identify and report the presence of a threat at trace levels of exposure."

Raman devices use laser light to excite molecular vibrations, which in turn causes a shift in the energy of the scattered laser photons, up or down, creating a unique visual pattern. In the case of trace amounts of molecules in gases or liquids, detection through ordinary Raman scattering is virtually impossible. However, the Raman signal can be enhanced via the SERS effect using metal nanoparticles.

Despite surface-enhanced Raman scattering being first observed in the late 1970s, efforts to provide reproducible SERS-based chemical sensors has been hindered by the inability to make large-area devices with a uniform SERS response. The ability to reproducibly pattern nanometer-sized particles in periodic arrays has finally allowed this requirement to be met.

"While many tools are currently available to detect trace amounts of chemical warfare and biological agents and explosive compounds, a device using SERS can be used to identify these minute quantities of the chemicals of interest by providing a 'fingerprint' of the material, which all but eliminates the prevalence of false alarms," says Glembocki.

SERS offers several potential advantages over other spectroscopic techniques because of its measurement speed, high sensitivity, portability, and simple maneuverability. SERS can additionally be used to enhance existing Raman technologies, such as the hand held and standoff units that are already in use in field applications.

Top spectra (red) displays SERS response of thiolphenol from NRL fabricated nanopillar arrays in comparison to a pure thiophenol solution (blue) — note the disparity in intensity favors the SERS measurement, despite having 10 million times (107) fewer molecules being probed. In order to determine the enhancement factor, the SERS response is compared to the neat solution, where the enhancement factor is the SERS intensity per molecule divided by the Raman intensity of the pure solution per molecule. The NRL arrays exhibit enhancements up to 100 million times (108). A 100,000 times magnified view of the gold coated, silicon nanopillars that make up the arrays used in the SERS measurements. Each array consists of 250,000 nanopillars with up to 400 arrays per wafer.


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