Proceedings Article | 11 May 2012
Proc. SPIE. 8358, Chemical, Biological, Radiological, Nuclear, and Explosives (CBRNE) Sensing XIII
KEYWORDS: Target detection, Principal component analysis, Statistical analysis, Deep ultraviolet, Sensors, Luminescence, Phosphorescence, Raman spectroscopy, Explosives, Chemometrics
Photon Systems in collaboration with JPL are continuing development of a new technology robot-mounted or hand-held
sensor for reagentless, short-range, standoff detection and identification of trace levels chemical, biological, and
explosive (CBE) materials on surfaces. This deep ultraviolet CBE sensor is the result of ongoing Army STTR and
DTRA programs. The evolving 15 lb, 20 W, lantern-size sensor can discriminate CBE from background clutter
materials using a fusion of deep UV excited resonance Raman (RR) and laser induced native fluorescence (LINF)
emissions collected is less than 1 ms. RR is a method that provides information about molecular bonds, while LINF
spectroscopy is a much more sensitive method that provides information regarding the electronic configuration of target
molecules.
Standoff excitation of suspicious packages, vehicles, persons, and other objects that may contain hazardous materials is
accomplished using excitation in the deep UV where there are four main advantages compared to near-UV, visible or
near-IR counterparts. 1) Excited between 220 and 250 nm, Raman emission occur within a fluorescence-free region of
the spectrum, eliminating obscuration of weak Raman signals by fluorescence from target or surrounding materials. 2)
Because Raman and fluorescence occupy separate spectral regions, detection can be done simultaneously, providing a
much wider set of information about a target. 3) Rayleigh law and resonance effects increase Raman signal strength
and sensitivity of detection. 4) Penetration depth into target in the deep UV is short, providing separation of a target
material from its background or substrate.