SBIR-STTR Award

ARPA has indentified the need for compact and mobile air sampling equipment with two uses: as a weapons of mass destruction (WMD) monitoring systems or as an air pollution detector. PHI proposes to meet these needs with a novel Raman Scattering and Flourescence instrument using a diode laser and a charge coupled device (CCD) or avalanche photodiode (APD) detector. The instrument selects the Raman or Fluorescence spectral lines to be studied with a circular variable filter (CVF) and a Fabry-Perot (FP) interferometer used in tandem. The instrument can separate Rayleigh scattering, Raman scattering, and Flourescence with spectral and time spectroscopy. Spectral coverage is from 0.5 to 1.1. micron, resolution is 2cm1` and sensitivity to parts per trillion. A conventional germanium detector of soft gamma rays or a novel gamma ray Compton scattering telescope system proprietary to PHI will map isomer radiation from the alpha decay of uranium of plutonium for nuclear WMD applications. PHI has assembled an outstanding technical team to perform this research and this team will show the feasibility of these concepts in Phase I. In Phase II, PHI hopes to guide the team to develop a prototype in a timely and cost effective manner. The aforementioned team includes: Dr. Anthony Hull of OCA Applied Optics Co. of Garden Grove CA, and Dr. Theodore Gay of PHI. Consultants include: Iowa State and Penn. State (Meteorology Dept.). All participants have many years of experience in the state of the art. Anticipated

Benefits:
The benefits and commercial applications of this proposed device include: Analysis of air pollution at low cost with a light weight, compact sensor constant monitoring and control of pollution from public utility and aircraft turbines; analysis of complex semiconductor and catalyst structures, such as superlattices; and portable analysis of biological compounds for real time diagnosis of disease.

DARPA has identified the need for a compact laser monitor suite, the CLM to detect chemical agents and explosives. This CLM system will detect terrorist threats to individual American citizens and to federal interests. The private sector needs variants of the CLM to detect the common pollutants released by industry and to increase fuel efficiency. In Phase I, PHI built and tested a breadboard of the CLM, the CLM1, on time and within budget. In Phase II, PHI will fabricate and field a commercial prototype of this monitor, the CLM2. The team will upgrade the breadboard with an innovative Raman and fluorescence spectrometer. The CLM2 will include a second laser that enables coherent Raman scattering from 500 to 900 nm at 0.01 nm resolution. PHI will conduct tests of the CLM2 on simulants of chemical agents and low budget explosives such as NH4NO3 powder. UCSD and PHI will use the CLM2 to monitor the combustion of fuels and toxic chemicals in an innovative UCSD counter flow burner. We will analyze the data and design an infrared version of the CLM2. PHI will also design and fabricate a breadboard of an innovative light triggered X-ray source and monitor system, the XRM. This XRM will acquire data on chemical agents and explosives located behind metal shields at spectral energies between 10 and 30 KeV. Anticipated

Benefits:
Benefits and commercial application of the compact monitor system include: detection of toxic chemical agents used for military and terrorist threats; spot analysis of air; water and soil pollution at low costs; increased turbine and automative engine efficiency; monitoring of industrial processes in the oil and paper and pulp industries; detection of threats in mail and crates at low cost; development of biological diagnostic tools.