SBIR-STTR Award

The broader impact/commercial potential of this Small Business Innovation Research (SBIR) Phase I project is to create an economical, high performance Terahertz (THz) spectrometer mounted to a consumer drone or Unmanned Aerial Vehicle (UAV) to allow testing of air for the presence of harmful compounds over a specific geographical location. A frequency domain THz spectrometer is capable of characterizing many different molecules and chemicals in a gas sample. Historically these spectrometers have been relegated to the laboratory because of their size and complexity. However, recent advancements have made it possible to build a lightweight spectrometer that can be mounted to a drone. This is significant because the ability to analyze samples locally removes the time and expense of collecting and shipping potentially dangerous compounds (i.e. chemical warfare agents or pollutants) to a laboratory for analysis. It also allows detection and classification to occur on short notice and without the need to subject personnel to the local environment. The THz Drone will allow immediate and accurate detection of many harmful compounds in the air. The proposed project will demonstrate a compact, battery operated, frequency domain THz photomixing spectrometer that is capable of Doppler limited molecular spectroscopy and is constructed predominantly from economical off-the-shelf fiber optic components in a highly compact, light-weight form factor. The brass-board instrument will incorporate an optical phase-modulation technique to remove the effects of coherent detection and it will have a greater than 2 THz bandwidth with a spectral purity of better than 100 kHz. After construction, the instrument will be employed to measure Doppler limited molecular transitions of carbon dioxide mixed with water vapor. Upon the successful demonstration of the capabilities of the instrument, a first-draft design for an integrated system weighing less than 3 kg and capable of being carried with a consumer drone will be generated as will a larger laboratory version of the instrument.

The broader impact/commercial potential of this Small Business Innovation Research (SBIR) Phase II project is to create an economical, light?weight, high performance Terahertz (THz) spectrometer to allow testing of air and fossil fuels for the presence of harmful compounds. A frequency domain THz spectrometer is capable of characterizing the different molecules and chemicals in a gas sample. Historically these spectrometers have been relegated to the laboratory because of their size and complexity but recent technical advancements have made it possible to build a spectroscopic THz sensor small enough and light enough to be flown on a consumer drone. The reductions in size and cost have opened the door to using THz sensors for emissions testing of ships entering U.S. waters or contaminant testing of fossil fuels at petroleum processing facilities. This is significant because the ability to analyze samples locally removes the time and expense of collecting and shipping potentially dangerous compounds (i.e. flammable compounds or pollutants) to a laboratory for analysis. It also allows detection and classification to occur on short notice and without the need to subject personnel to the local environment. The proposed project will produce the first article of a compact, battery operated, autonomously operating spectroscopic THz sensor capable of mixed gas analysis to parts per million sensitivities. It will be constructed predominantly from economical off?the?shelf fiber optic components in a novel highly compact, light?weight form factor. In order to achieve the high sensitivities, the spectroscopic THz sensor will incorporate: high fidelity lasers from the telecommunications industry, custom designed and fabricated high efficiency, hermetically sealed photomixers, a folded, light?weight, carbon fiber sample cell incorporating patented 3D printed mirror technology and a patented optical phase?modulation technique that removes the effects of coherent detection. The instrument will first be employed for laboratory based measurements of sulfur-containing contaminants in gas flows. Upon the successful demonstration of the capabilities of the instrument, a first article will be used in initial testing and collaborative field work. Sales of a larger laboratory instrument based on the same technology will begin simultaneously.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.