Saturation of light-current characteristics of high-power laser diodes (λ = 1.0–1.8 μm) under pulse operation

“…As we showed recently [1,3], the charge-carrier concentration increases in the active region of the laser structure and in the waveguide layers at high levels of current pumping; this increase is a result of saturation of the rate of stimulated recombination. In lasers based …”

“…In the long-wavelength laser structures ( λ = 1.88 µ m), the experimental value of internal optical losses was reduced to 1 cm -1 (Fig. 2), which is comparable to the value of internal optical losses at the oscillations' threshold for lasers with the wavelength of 1.04 µ m. In the continuous-wave [9,10] and pulsed [2] modes of oscillations at high excitation levels, the optical-radiation power of the lasers with the wavelength of 1.75-1.88 µ m is several times lower than that of the shortwavelength ( λ = 1.04 µ m) lasers [1,[3][4][5][6][7][8]. In Fig.…”

“…Our recent studies [1,[3][4][5] showed that the chargecarrier concentration increases in the active region of a semiconductor laser beyond the lasing threshold at a high level of current pumping. The increase in concentration sets in when the rate of stimulated recombination becomes equal to the rate of energy relaxation of electrons in a quantum well of the active region.…”

“…Nevertheless, irrespective of the emission wavelength and the used system of alloys, a retardation of the growth (saturation) of emitted optical power is observed for semiconductor lasers. This process is especially pronounced in long-wavelength lasers in which the highest attainable emission power is severalfold lower than in the lasers of the near-infrared (near-IR) region of emission [1][2][3].…”

10.1007/s11453-008-1015-z

“…As we showed recently [1,3], the charge-carrier concentration increases in the active region of the laser structure and in the waveguide layers at high levels of current pumping; this increase is a result of saturation of the rate of stimulated recombination. In lasers based …”

“…In the long-wavelength laser structures ( λ = 1.88 µ m), the experimental value of internal optical losses was reduced to 1 cm -1 (Fig. 2), which is comparable to the value of internal optical losses at the oscillations' threshold for lasers with the wavelength of 1.04 µ m. In the continuous-wave [9,10] and pulsed [2] modes of oscillations at high excitation levels, the optical-radiation power of the lasers with the wavelength of 1.75-1.88 µ m is several times lower than that of the shortwavelength ( λ = 1.04 µ m) lasers [1,[3][4][5][6][7][8]. In Fig.…”

“…Our recent studies [1,[3][4][5] showed that the chargecarrier concentration increases in the active region of a semiconductor laser beyond the lasing threshold at a high level of current pumping. The increase in concentration sets in when the rate of stimulated recombination becomes equal to the rate of energy relaxation of electrons in a quantum well of the active region.…”

“…Nevertheless, irrespective of the emission wavelength and the used system of alloys, a retardation of the growth (saturation) of emitted optical power is observed for semiconductor lasers. This process is especially pronounced in long-wavelength lasers in which the highest attainable emission power is severalfold lower than in the lasers of the near-infrared (near-IR) region of emission [1][2][3].…”

10.1007/s11453-008-1015-z

“…Continuous-wave semiconductor lasers operating in this wavelength region have already demonstrated close-to-limiting radiation characteristics [2 - 4]. However, in the case of pumping by high-current pulses with durations of several hundreds of nanoseconds, the light - current characteristics of theses lasers saturate independently of the growth technology and the composition of the used semiconductor solid solutions [2,3,5]. The reasons for the saturation of pulsed power at high pump currents were studied in a number of works, which considered the factors responsible for this saturation.…”

Saturation of light – current characteristics of high-power lasers (λ = 1.0 – 1.1 mm) in pulsed regime

11.1 Quantum dot diode lasers