Cobolt

It is only in the last two decades that Raman spectroscopy has begun to realize its potential as an almost universally applicable analytical technique from materials and life sciences applications to point of care analysis. This is pri­marily thanks to the availability of compact laser sources, high sensitivity cameras and high resolution compact spectrometers.

The ultimate instrumentation for trace gas analysis and detection in air quality monitoring as well as industrial process control would be one that can simultaneously provide a sensitive, selective, and fast, multi-gas measurement with wide dynamic range all in a compact and robust system. One of the few such promising technologies that can deliver these requirements is laser based photoacoustic spectroscopy (PAS).

Although the technique of Photo-Acoustic Spectroscopy (PAS) has been around for over a century, the method has been somewhat limited in sensitivity due to the microphone and laser technology. In recent years improvements have been made on both these fronts which mean that PAS is now viewed as an advanced method for very sensitive trace gas analysis and detection.