A43F-0358
PIGC™ – A low cost fugitive emissions and methane detection system using advanced gas filter correlation techniques for local and wide area monitoring

Thursday, 17 December 2015
Poster Hall (Moscone South)
Richard L. Lachance1, Larry L Gordley2, Benjamin T Marshall2, John Fisher3, Greg Paxton2, Joe F Gubeli4 and PIGC™ Team, (1)Organization Not Listed, Washington, DC, United States, (2)GATS, Inc., Newport News, VA, United States, (3)Brandywine Photonics LLC, Exton, PA, United States, (4)Jefferson Lab, Newport News, VA, United States
Abstract:
Currently there is no efficient and affordable way to monitor gas releases over small to large areas. We have demonstrated the ability to accurately measure key greenhouse and pollutant gasses with low cost solar observations using the breakthrough sensor technology called the “Pupil Imaging Gas Correlation”, PIGC™, which provides size and complexity reduction while providing exceptional resolution and coverage for various gas sensing applications. It is a practical implementation of the well-known Gas Filter Correlation Radiometry (GFCR) technique used for the HALOE and MOPITT satellite instruments that were flown on successful NASA missions in the early 2000s. This strong space heritage brings performance and reliability to the ground instrument design.

A methane (CH4) abundance sensitivity of 0.5% or better of ambient column with uncooled microbolometers has been demonstrated with 1 second direct solar observations. These under $10 k sensors can be deployed in precisely balanced autonomous grids to monitor the flow of chosen gasses, and infer their source locations. Measureable gases include CH4, 13CO2, N2O, NO, NH3, CO, H2S, HCN, HCl, HF, HDO and others.

A single instrument operates in a dual operation mode, at no additional cost, for continuous (real-time 24/7) local area perimeter monitoring for the detection of leaks for safety & security needs, looking at an artificial light source (for example a simple 60 W light bulb placed 100 m away), while simultaneously allowing solar observation for quasi-continuous wide area total atmospheric column scanning (3-D) for environmental monitoring (fixed and mobile configurations). The second mode of operation continuously quantifies the concentration and flux of specific gases over different ground locations, determined the amount of targeted gas being released from the area or getting into the area from outside locations, allowing better tracking of plumes and identification of sources.

This paper reviews the measurement technique, performance demonstration and grid deployment strategy.