Standard and phase-matched grazing-incidence and distributed-feedback FIR gas lasers

In this paper we review theoretical and experimental studies on optically pumped 496 m CH₃F DFB lasers of different configurations, including grazing-incidence arrangement and phase matching by a gap in the periodic structure. These configurations combine the simple tuning mechanism of grazing-incidence systems with the high frequency selectivity of DFB. Our theoretical considerations based on coupled-wave theory are concerned with the dispersion relations and resonance conditions of standard and phase-matched DFB and grazing-incidence gas lasers. We have succeeded in calculating the relevant TM coupling coefficients for lasers with rectangular periodic waveguides. For laser cavities with various continuous gratings we have measured the resonant heights and tuning angles of the laser oscillations of first- and second-order DFB. We have found good agreement with theoretical resonance conditions. In order to improve the mode selectivity and to attain single longitudinal mode operation, which is a requirement for semiconductor lasers in many applications, we have introduced variable gaps in the center of the gratings. These provide phase matching and gap modes. We have compared the measured gap modes with our theory and found agreement in specific cases, where the phase-matched cavity implies single-mode laser operation. Our results on standard and phase-matched DFB cavities promise an improvement of the performance of phase-matched semiconductor lasers with respect to small bandwidth and optimized output power.