1 Introduction
Currently, extensive research has shown that diode-pumped metastable rare gas lasers (DPRGLs) have the potential for high-power laser output with excellent beam quality[ Reference Han and Heaven1– Reference Demyanov, Kochetov and Mikheyev11]. Han and Heaven[ Reference Han and Heaven1] first proposed the laser concept in 2012, in which the gain and lasing were demonstrated. DPRGLs use metastable rare gas atoms (Rg* represents the metastable rare gas atoms Ar*, Kr* and Xe*) excited through electron collisions as the laser gain medium. Due to the similarity of the electronic configuration and optical property between the metastable rare gas atom and the alkali atom, DPRGLs are expected to inherit the single-aperture power-scaling potential of diode-pumped alkali vapor lasers (DPALs)[ Reference Eshel and Perram3, Reference Zweiback, Komashko and Krupke12, Reference Krupke13]. In addition, using rare gas as the laser medium is convenient and safe for high-power laser systems.
DPRGLs are usually expected to operate in a three-level system, as illustrated in Figure 1. The energy levels represented by Paschen and Racah notation are displayed, which takes Kr as an example. In the laser cycle, the atom at 1s5 (Kr*) is preliminarily produced by electron collisions. Then the atom is excited to 2p9 by the diode pumping light and then relaxed to 2p10 through the collisional process by helium. The laser occurs through the stimulated emission transition from 2p10 to 1s5.
After a proof-of-concept demonstration of the laser using an optical parametric oscillator as a surrogate pump source in 2012, the first diode-pumped Ar* laser was realized in 2013[ Reference Han, Glebov, Venus and Heaven14]. Subsequently, Rawlins et al.[ Reference Rawlins, Galbally-Kinney, Davis, Hoskinson, Hopwood and Heaven4] achieved a highly efficient continuous-wave Ar* laser with an apparent optical conversion efficiency of 55%. The research of Han et al. [ Reference Han, Heaven, Moran, Pitz, Guild, Sanderson and Hokr2] revealed that persistent, high-density and large-volume generation of metastable laser could be obtained using a high-repetition nanosecond pulsed direct current (DC) discharge, and a continuous-wave Ar* DPRGL was realized with 4 W output. Eshel and Perram[ Reference Eshel and Perram3] established an advanced model to evaluate the scaling potential of DPRGLs, which theoretically demonstrated the feasibility of a highly efficient 100 kW-level Ar* laser. Wang et al.[ Reference Wang, Yang, Liu, Han, Wang and Xu8, Reference Xu, Wang and Yang9] recently proposed a new scheme for extracting lasing in a plasma jet, potentially overcoming the power-scaling obstacles in previously used confined discharges.
Until now, most research on DPRGLs has been carried out using Ar* as the gain medium[ Reference Emmons, Weeks, Eshel and Perram15– Reference Hoskinson, Gregorío, Hopwood, Galbally-Kinney, Davis and Rawlins18] and a little on the Xe* laser[ Reference Sanderson, Ballmann, Han, Clark, Hokr, Xu and Heaven5, Reference Mikheyev, Han, Clark, Sanderson and Heaven19, Reference Demyanov, Kochetov, Mikheyev, Azyazov and Heaven20]. The only research for the Kr* laser is on concept verification and kinetics investigation[ Reference Han and Heaven1, Reference Han and Heaven21], and no study using high-power diode pumping has been reported. As compared with Ar*, Kr* has some noteworthy characteristics. Firstly, Kr* has lower excitation energy (Kr*: 9.92 eV versus Ar*: 11.55 eV), which could reduce the requirement for gas discharge and is beneficial to generate high-density metastables. Secondly, the quantum efficiency of Kr* is higher (Kr: 91% versus Ar: 89%), meaning a better optical conversion efficiency and less waste heat. Thirdly, the energy difference between the 2p8 and 2p9 levels of Kr is only 13 cm–1, which means that a significant fraction of the population will locate among the three upper levels (2p8, 2p9 and 2p10), creating conditions suitable for multi-wavelength laser emission.
Energy levels and transition process of Kr (1s and 2p).
Schematics of the experimental setup of a diode-pumped Kr* laser. BS, beam splitter; DM, dichroic mirror; OC, output coupler; LPF, long pass filter; PD, photodetector.
In this work, we aim to explore the performance of a diode-pumped Kr* laser. The Kr* was generated using a repetitive nanosecond pulsed DC discharge. Under 811.3 nm diode pumping, a Kr* laser with dual wavelengths was demonstrated. The population distribution in the 2p levels and population time evolution in the 1s levels were monitored and analyzed to understand the laser kinetics further.
2 Experimental setup
The main experiment setup of the diode-pumped Kr* laser is shown in Figure 2. The gas discharge chamber was made of poly-ether-ether-ketone (PEEK) plastic with optical windows installed around four surfaces. Two circular plane electrodes (tungsten copper alloy) were mounted face-to-face in the chamber’s center. They had a cross-section of π × 2.52 mm2 and were separated by a distance of 3 mm. A dry scroll vacuum pump (IDP-15, Agilent Technologies) was used to evacuate impurified gas from the chamber in advance. The mixed Kr:He gas (1:49 and 99.999% in purity) was fed into the gas chamber. A mass flow meter was used to control the flow rate at 2 L/min, and a choke valve was used to adjust the pressure inside the chamber.
The plasma was produced by gas discharge using a nanosecond pulsed DC power source, which could run at a voltage of approximately 4 kV, a pulse duration of 80 ns and a maximum frequency of 200 kHz. When the pulsed DC power supply was turned on, the generated plasma could fill the whole space between the two electrodes. The discharge voltage between the two electrodes was measured by a high-voltage differential probe (P6015A, Tektronix).
In Figure 2, a longitudinal pump scheme was used to excite the Kr* laser. The wavelength of the diode pumping source was locked by a volume-Bragg grating at the central wavelength (1s5→2p9) of 811.29 nm, and the pump source could produce approximately 7.6 W output power with a linewidth of 0.1 nm (full width at half maximum (FWHM)). The measured absorption bandwidth of the pump transition was 0.029 nm (FWHM) at the pressure of 600 Torr and 0.062 nm at the pressure of 1450 Torr. The absorption bandwidth has an approximately linear change with the increasing mixed gas pressure (Kr:He = 1:49). A beam splitter (BS1) placed in front of the pump source could reflect approximately 5% of the pump light into an integrating sphere connected to an optical spectrum analyzer (OSA, AQ6370D, Yokogawa) for wavelength monitoring. A convex lens (lens, f = 150 mm) was used to focus the pump light into the central region of the plasma. The resonator with a length of approximately 160 mm consisted of a plane dichroic mirror (DM) and an output coupler (OC). The DM has more than 95% reflectivity at 892/877 nm and more than 95% transmittance at 811 nm. The OC is a concave mirror (500 mm radius of curvature) with approximately 90% reflectivity at 892 nm, approximately 80% reflectivity at 877 nm and more than 99% transmittance at 811 nm. To separate the Kr* laser from the pump light, a beam splitter (BS2, ~20% transmittance at 892 nm, ~5% transmittance at 877 nm and >99% reflectivity at 811 nm) was used to reflect most of the transmitted pump light into a pump dump, and a long pass filter (LPF, Thorlabs, cut at the wavelength 850 nm) was used to further filter out the residual pump light. A photodetector (PD1, DET10A2, Thorlabs) was used to collect the signal of the Kr* laser.
The atomic density measurement device was placed perpendicular to the pump path. The single-frequency probe laser (DL, UniQuanta, Inc.) has an approximately 1 MHz linewidth and a wide tuning range of more than 1 nm. It was used to scan the absorption spectrum of the 1s5→2p9 transition. PD2 was used to measure the absorption signal of the probe light. After the absorption line shape was obtained, the absorption cross-section could be deduced and the number density of Kr* could be calculated using Beer–Lambert’s law.
3 Experimental results
The discharge apparatus could produce Kr* with a number density higher than 1013 cm–3, and the atomic density evolution is plotted in Figure 3. The pressure was increased from 496 to 1465 Torr while keeping the voltage at a constant value of approximately 3 kV. The peak atomic density increased with elevating pressure, partially due to the increased absolute amount of Kr. The time duration between the peak value and 1/e of the atomic density was used to represent the apparent lifetime of Kr*. It decreased from 5.1 μs (at 496 Torr) to 1.67 μs (at 1465 Torr), mainly due to the more frequent quenching collisions at higher pressure.
Time-dependent number density of Kr* at different pressures.
The spectrum of the Kr* laser is shown in Figure 4, which presents the dual laser lines of 877 nm (2p8→1s4) and 892 nm (2p10→1s5). The 892 nm spectrum originated from the expected three-level cycle 1s5→2p9→2p10→1s5, while the 877 nm spectrum originated from the additional channel 1s5→2p9→2p8→1s4. The energy gap between the 2p8 and 2p9 levels is only 13 cm–1. A kinetics study in Kr showed that the populations of 2p8 and 2p9 were in Boltzmann thermal equilibrium due to the fast collisional mixing rate at atmospheric helium[ Reference Han and Heaven21]. So, a considerable amount of the population was transferred to the 2p8 state (~70% relative to 2p9), which supported the lasing due to population inversion between 2p8 and 1s4.
Spectrum of the output laser (877 and 892 nm) and the pump stray light (811 nm).
The time-dependent traces of the discharge voltage, the number density of 1s5 and the laser intensity are shown in Figure 5. The discharge operated at a voltage of approximately 3.6 kV with a frequency of 200 kHz. After each discharge pulse, the number density of 1s5 reached a peak value of approximately 5.5×1013 cm–3 and decreased to 1×1013 cm–3 within 5 μs under the pressure of 1125 Torr. When the pump was on, pulsed Kr* lasing was observed, with an initial spike and a decreased trend similar to the atomic density evolution.
Time-dependent traces for the voltage between two electrodes, the number density of Kr (1s5) under discharge only and the laser intensity under 7.6 W pump power.
The averaged power of the Kr* laser is shown in Figure 6. The laser power increased linearly with pressure, which may arise from the increased number density of Kr* and faster collisional relaxation from 2p9 to the upper laser levels. At the pressure of 1430 Torr, the maximum output power reached approximately 100 mW and the absorbed pump power was approximately 1 W, which meant that the optical conversion efficiency was approximately 10%. The peak power calculated from the lasing trace was approximately 1.1 W.
Laser power of the Kr* laser with increasing pressure, under 7.6 W pump power.
4 Discussion
The dual-wavelength Kr* laser was achieved with an optical conversion efficiency of approximately 10%. To investigate the muti-wavelength mechanism and the low optical conversion efficiency, the methods of optical emission spectroscopy (OES) and tunable diode laser absorption spectroscopy (TDLAS) were employed to study the population distribution and evolution of the populations in this Kr* laser.
4.1 Population distribution of the 2p energy levels
The line-ratio method of OES used to obtain the Rg (2p) population distribution was described in detail in our previous work[ Reference Liu, Wang, Sun, Zhao, Yang, Yang, Wang, Han and Xu22]. Transitions from the 2p states with strong emission intensity were chosen to reveal the 2p populations due to their high signal-to-noise ratio. The population distribution of the total 2p levels at pressure of approximately 1100 Torr is presented in Figure 7(a). When only discharge existed (‘discharge only’), a small number of atoms occupied the 2p levels. When the diode pump light entered the medium with no lasing (‘pumping without a resonator’), a significant increase in population at energy levels of 2p8, 2p9 and 2p10 was observed. In addition, some excited atoms relaxed to adjacent energy levels of 2p6 and 2p7, while a few atoms were transferred to higher levels (2p1 to 2p5). When the resonator was established with lasing (‘pumping with lasing’), approximately 4.5% of the atoms in the 2p10 level were consumed due to stimulated radiation. In addition, the increase in population at the 2p8 and 2p9 levels was caused by the enhanced pump absorption in the laser cycle, resulting in more Kr* being pumped to the 2p9 level and simultaneously relaxed to the 2p8 level. The population distribution suggested that the observed dual-wavelength emission was attributed to a significant proportion of atoms populated in the 2p8 and 2p10 levels.
To investigate the relationship between power and pressure (Figure 6), the population (2p8–2p10) in the condition of ‘pumping with lasing’ was studied with a wide range of pressure, plotted in Figure 7(b). The proportion of populations in 2p1–2p7 was small (~10% at a pressure of 400 Torr, ~1% at a pressure of 1400 Torr) and is not shown here. The population growth of 2p10 was significant with increasing pressure, whereas 2p9 exhibited weaker growth. Furthermore, 2p8 also experienced increased growth under pressure until reaching a plateau at atmospheric pressure. Therefore, the observed increase in the output power can be ascribed to an increased upper laser level population.
(a) Population distribution in Kr (2p) (the error bar represents standard deviation) and (b) population of Kr (2p8, 2p9 and 2p10) versus pressure.
Time-dependent traces of the number density of the 1s5 and 1s4 levels. (The oscillation in the figure is the noise of the discharge.)
4.2 Population evolution of the 1s energy levels
Similar to Ar[ Reference Han, Glebov, Venus and Heaven14, Reference Wang, Liu, Yang, Wang and Xu23], for the 1s manifold of Kr, the 1s4 and 1s5 levels are the primary influencing levels. To reveal the kinetics of 1s4 and 1s5, two probe lasers with wavelengths of 819 nm (1s4→2p6) and 811.3 nm (1s5→2p9) were used to monitor the absorption signal of the 1s4 and 1s5 levels simultaneously. The population evolutions are shown in Figure 8. With discharge only, a certain number of atoms were excited to the 1s4 and 1s5 levels. When the pump was on, the number density of 1s5 decreased, while that of the 1s4 increased. The accumulation in the 1s4 level mainly arose from the spontaneous radiation of the 2p8 and 2p10 levels. Considering the spontaneous emission coefficients and the populations of the two levels (Figure 7), the contributions that repopulated 1s4 were nearly 3.8:1 for 2p8 and 2p10. The time-dependent trace of 1s4 also showed that the atomic relaxation from 1s4 to 1s5 was slower than the spontaneous radiation. These factors caused the depletion of Kr* and the early termination of the laser. The accumulation of 1s4 could be significantly improved by increasing the 1s5 density and using a dual-wavelength pump scheme[ Reference Sun, Zuo, Wang, Han and Heaven6, Reference Yang, Yu, Wang, Lu and Xu7].
5 Conclusion
In conclusion, a dual-wavelength diode-pumped metastable Kr laser was demonstrated for the first time. The high number density of Kr* (>1013 cm–3) was obtained in a wide pressure range in the pulsed DC discharge. The dual wavelengths of 877 and 892 nm with an averaged power of approximately 100 mW (peak power ~1.1 W) and an apparent optical conversion efficiency of approximately 10% with respect to the absorbed pump power were achieved. In order to explain the dual-wavelength phenomenon and the low efficiency, the population distribution of the 2p levels was revealed using the OES method, and the population evolution of the 1s levels was monitored using the TDLAS method. The dual-wavelength output mainly arose from the large population in the 2p8 and 2p10 levels. The low efficiency was caused by several improvable reasons, including insufficient column density of Kr*, low pump intensity, the accumulation in 1s4, etc.
In the next step, conditions should be synthetically optimized to validate the high-power and high-efficiency potential of the Kr* laser. Firstly, compared with Ar*, Kr* could sustain a stable discharge and larger volume under higher pressure, and a higher column density may be obtained by optimizing the discharge parameters. Secondly, the currently available pump intensity (~0.5 kW/cm2) was far below the requirement, approximately near the threshold. The diode pump source power and intensity will be improved. Thirdly, an increase in the metastable density and the dual-wavelength pumping scheme is expected to eliminate the accumulation effect of 1s4.
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