Quantum-Limited FM-Spectroscopy with a Lead-Salt Diode Laser A Comparison of Theoretical and Experimental Data

Ultrasensitive absorption spectroscopy of NO 2 was performed with a tunable lead-salt diode laser (TDL) using a single-tone high-frequency modulation (FM) technique. With a detection bandwidth of 200 kHz, an optical density of 2.7 × 10-5 was detectable at SNR of 1. The detectable optical density could be further improved by reducing the detection bandwidth in agreement with the A~f relationship, reaching 2.5 × 10 -6 at a detection bandwidth of 1.56kHz. Normalized to 1 Hz bandwidth, the demonstrated performance would then correspond to a detectable optical density of 5.9 x 10 -s. This detection limit agrees well with the calculated "quantum limited" performance based on the measured laser power, modulation index, noise figure of the electronic components, and other parameters of the apparatus. These measurements and calculations show that by implementation of the FM technique, the sensitivity of the present TDL absorption spectrometers (TDLAS) can be improved by at least a factor of 10 and possibly even of 100. Such a sensitivity improvement would greatly extend the applicability of TDLAS for trace gas analysis, especially in atmospheric monitoring.