Bismuth nanosheets as a <i>Q</i>-switcher for a mid-infrared erbium-doped SrF<sub>2</sub> laser

Jingjing Liu; Hao Huang; Feng Zhang; Zhen Zhang; Jie Liu; Han Zhang; Liangbi Su

doi:10.1364/PRJ.6.000762

1. INTRODUCTION

Mid-infrared solid-state lasers have attracted increasing attention owing to their broad applications in the military, medical treatments, and air pollution monitoring ^[1,2]. Mid-infrared solid-state lasers have a low cost, simple structure, and rare-earth ions doped crystals as the gain medium. They are directly pumped by the laser diode (LD) and can thus effectively achieve miniaturization and high efficiency. ${Tm}^{3 +}$ , ${Er}^{3 +}$ , and ${Ho}^{3 +}$ are the main rare-earth ions emitting at 2–5 μm in the mid-infrared region ^[3–7]. Indeed, ${Er}^{3 +}$ -doped lasers have efficient emissions involving a transition from the ${}^{4}{I_{11 / 2}}$ to the ${}^{4}{I_{13 / 2}}$ state around 2.8 μm, which is in the strong absorption region of water. They are thus an ideal pumping source for mid-infrared and far-infrared optical parametric oscillations (OPOs) ^[8].

However, the lifetime of the upper laser energy level ( ${Er}^{3 +} : {}^{4}{I_{11 / 2}}$ ) is always shorter than that of the lower laser energy level ( ${Er}^{3 +} : {}^{4}{I_{13 / 2}}$ ) in 2.8 μm ${Er}^{3 +}$ -doped laser materials. This phenomenon is known as the self-terminating process. Generally, this problem can be easily solved. Improving the doping concentration of ${Er}^{3 +}$ is one effective way to achieve the desired laser output: with the increase in ${Er}^{3 +}$ doping concentrations, the lifetime of ${Er}^{3 +} : {}^{4}{I_{13 / 2}}$ decreases faster than that of ${Er}^{3 +} : {}^{4}{I_{11 / 2}}$ owing to the cross relaxation between the two levels. Furthermore, codoping with deactivating ions such as $\Pr^{3 +}$ and ${Nd}^{3 +}$ is another effective way to depopulate the ${Er}^{3 +} : {}^{4}{I_{13 / 2}}$ level ^[9–11]. However, only few studies have reported successful laser outputs. In ${SrF}_{2}$ and ${CaF}_{2}$ crystals, the trivalent rare-earth ions tend to form clusters even at low doping concentrations ^[12]. Furthermore, the phonon energy is lower in fluoride materials than in oxide materials, which can greatly reduce the probability of nonradiative transitions ^[13].

In recent years, two-dimensional (2D) materials have attracted much attention owing to their outstanding properties and widespread applications, particularly as optical modulators in pulse lasers. Owing to the large operating bandwidth, controllable bandgap, and easy fabrication method, 2D materials, including the graphene family ^[14–19], transition metal dichalcogenides ^[20–23], topological insulators ^[24–28], phosphorus ^[29–34], and the recently discovered MXene ^[35] and antimonene ^[36,37], have been considered as low-cost substitutes for saturable absorbers (SAs) in semiconductor saturable absorber mirror (SESAM) devices. Bismuth nanostructures, a novel 2D material, show unique electronic and optical properties. With their moderate bandgap, high carrier mobility, and high stability at room temperature, bismuth nanostructures have become an increasingly interesting topic of discussion for researchers ^[38]. The saturable absorption property of bismuthene was first demonstrated in a 1559 nm fiber laser by Lu et al. ^[39]. However, to the best of our knowledge, the application of bismuth nanosheets (Bi-NSs) as an SA in the mid-infrared spectral region has not been reported.

In this work, by using Bi-NSs as an SA, a stable passively $Q$ -switched ${Er}^{3 +} : {SrF}_{2}$ laser was obtained. The saturable absorption behavior of Bi-NSs is demonstrated at 2.8 μm. In addition, this study provides a detailed analysis of the passively $Q$ -switched laser, including the variation of output power, pulse width, and repetition rate under different transmissions of output mirrors.

2. CHARACTERIZATIONS OF THE BI-NSs SA AND EXPERIMENTAL SETUP

The Bi-NSs were synthesized from bismuth powder using a sonication method. In a typical procedure, 200 mg of bismuth powder was added into a glass bottle with 100 mL of pure $N$ -methylpyrrolidone (NMP), followed by 6 h in an ice bath (SBL-22DT, with a power of 70% of 600 W). Then, the solution was probe sonicated for 24 h (BILON-1800Y, with a power of 60% of 1800 W) and kept in an ice bath for another 6 h. After that, the solution was centrifuged for 20 min at a speed of 3000 r/min. The supernatant was collected and centrifuged for another 20 min at a speed of 7000 r/min, and the Bi-NSs were finally obtained as the precipitate. The precipitate was washed twice with deionized water. Then, trichloromethane was added, and the solution was obtained after ultrasonication for 2 h. Finally, 100 μL of solution was spin coated at a speed of 1000 r/min for 15 s for the uniform adhesion of the Bi-NSs on fused quartz plates (JGS3 with 1 mm thickness). The structure of the Bi-NSs was confirmed by high-resolution transmission electron microscopy (HRTEM), as shown in Fig. 1(a). The Raman spectrum of Bi-NSs is shown in Fig. 1(b). Two peaks near 69 and $95 {cm}^{- 1}$ are indicative of the bismuth structure, which correspond to an earlier report ^[40]. To identify the thickness of the Bi-NSs, the atomic force microscopy (AFM) was taken. As shown in Figs. 1(c) and 1(d), the AFM image shows that the thickness of the Bi-NSs was no more than 2.5 nm.

Figure 1.(a) HRTEM image, (b) Raman spectrum, (c) AFM image of the bismuth nanosheets, and (d) typical height profiles.

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The nonlinear absorption mechanism of the Bi-NSs has been described in detail in Ref. ^[38]. The nonlinear optical properties of Bi-NSs SA were characterized by $Z$ -scan method with a nanosecond pulsed laser at 2.8 μm. The repetition rate is 50 kHz, and the pulse duration is 50 ns. The beam waist was about 60 μm, and the Rayleigh length was about 0.2 mm. The transmittance has a relation with the input optical intensity by the formula ^[41] where $α_{s}$ is the saturable absorption, also defined as the modulation depth, $α_{ns}$ is the nonsaturable loss, and $I_{s}$ is the saturable intensity. By fitting the experimental data, the nonlinear transmittance curve is shown in Fig. 2. The modulation depth and saturation fluence are found to be 1.82% and $3.59 kW / {cm}^{2}$ , respectively. Considering the Fresnel reflection loss of the JGS3 substrate, the nonsaturable loss of the Bi-NSs SA was calculated to be about 3.7%.

Figure 2.Nonlinear transmission of Bi-NSs SA.

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A schematic of the experimental device is shown in Fig. 3. The pump source was a commercial 972 nm fiber-coupled LD with a core diameter of about 50 μm and a numerical aperture (NA) of 0.15. The pump light was transmitted through the fiber and expanded into the gain medium by a coupling system of 1:2. The 3 at. % ${Er}^{3 +} : {SrF}_{2}$ crystal was grown by the traditional Bridgman method, which is described in detail in Ref. ^[42]. The uncoated ${Er}^{3 +} : {SrF}_{2}$ crystal was mounted on a copper block stabilized at 12°C by cycling cooling water. The laser resonator consists of a concave mirror (IM) and a plane output coupler (OC), with a physical length of about 48 mm. The IM with a 100 mm radius of curvature was antireflection coated for 974 nm and high-reflection coated for 2.7–2.95 μm. For the OC, we used different coated plane mirrors with transmissions of 1%, 3%, and 5% for 2.7–2.95 μm.

Figure 3.Schematic of the passively $Q$ -switched ${Er}^{3 +} : {SrF}_{2}$ laser with a Bi-NSs SA.

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3. RESULTS AND DISCUSSION

Continuous-wave (CW) laser operation was first carried out with different OC transmissions, and the average output powers are shown in Fig. 4. With an OC transmission of 3% at an absorbed pump power of 1.97 W, a maximum output power of 393 mW and corresponding slope efficiency of 21.3% were obtained. The Bi-NSs were used as the SA and inserted into the resonator to operate the laser in the passively $Q$ -switched regime. By carefully adjusting the position and angle of the Bi-NSs SA, the output laser displayed stable pulse repetition rates and uniform pulse trains when the absorbed pump power reached about 1 W. Under the same incident pump power and OC transmission, the maximum average output power was 226 mW, with a slope efficiency of 13.6%. Figure 5 shows the $Q$ -switched output power as a function of the absorbed pump power with different OC transmissions. The inset (a) shows the fluctuation of the maximum output power was about 8.4% for 70 min detection. Figures 6(a) and 6(b) display the laser beam profile and light intensity distribution, respectively, which were recorded by a detector (NS2-Pyro/9/5-PRO, Photon). The results indicate that the generated beam has an excellent ${TEM}_{00}$ transversal profile.

Figure 4.CW output power versus the absorbed pump power for different OC transmissions.

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Figure 5. $Q$ -switched output power versus the absorbed pump power for different OC transmissions. Inset (a) shows the maximum output power versus time.

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Figure 6.(a) Laser beam profile and (b) 3D light intensity distribution recorded at the maximum output power for the $Q$ -switched laser.

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The pulse repetition rate, pulse duration, single-pulse energy, and peak power as functions of the absorbed pump power for different OC transmissions are shown in Figs. 7(a)–7(d). With increasing absorbed pump power, the repetition rate and peak power increased and the pulse duration gradually decreased. The maximum output power, pulse repetition rate, pulse duration, single-pulse energy, peak power, and wavelength under different OC mirrors were recorded at the absorbed power of 1.97 W and are detailed in Table 1. According to these results, the best OC transmission is around 3% under the same conditions. Figure 8 shows the typical pulse trains recorded at different time scales by a digital oscilloscope (Tektronix DPO4104, 1 GHz bandwidth). At the maximum absorbed pump power, the repetition rate recorded at 400 μs/div was 56.2 kHz and the single-pulse duration recorded at 2 μs/div was 980 ns.

Table 1. Experimental Results Achieved under Different OC Mirrors

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Table 1. Experimental Results Achieved under Different OC Mirrors

OC Transmission	Max. Output Power (mW)	Repetition Rate (kHz)	Pulse Width (ns)	Single-Pulse Energy (μJ)	Peak Power (W)	Wavelength (nm)
1%	162	39.1	1170	4.14	3.54	2799.1
3%	226	56.2	980	4.02	4.10	2730.5+2752.2
5%	205	47.6	1237	4.30	3.48	2732.6+2737.0

Figure 7.(a) Pulse repetition rate, (b) pulse duration, (c) single-pulse energy, and (d) peak power versus the absorbed pump power for different OC transmissions.

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Figure 8. $Q$ -switched pulse trains recorded at 2 and 400 μs/div, under an absorbed pump power of 1.97 W for the OC transmission of 3%.

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Figure 9 shows the reliability of the laser emission spectra recorded under the OC transmission of 3% by an optical spectrum analyzer (MS3504i). The central wavelengths are 2729.5 and 2751.7 nm for the CW laser, and the full width at half-maximum (FWHM) are 0.70 and 1.0 nm following a Gaussian fit. The laser emission spectrum is consistent with the emission spectrum of the ${Er}^{3 +} : {SrF}_{2}$ crystal reported in Ref. ^[42], which exhibits two emission peaks around 2727 and 2745 nm. The simultaneous dual-wavelength laser can be used as a light source for the generation of terahertz emission ^[43]. For the $Q$ -switched laser operation, the central wavelengths are 2730.5 and 2752.2 nm and the corresponding FWHM are 0.91 and 0.9 nm, respectively. A redshift in the lasing wavelength was observed. Reference ^[44] describes the cause of the phenomenon in detail. The short wavelengths located near the emission peaks are more likely to oscillate for the CW laser. When inserting Bi-NSs into the cavity, the insertion loss of the fused quartz substrate was high and the gain at different wavelengths was discrepant, so the wavelength shifted toward either longer or shorter wavelengths ^[45]. As the intracavity loss changed, the Stark energy levels of ${Er}^{3 +}$ split and the laser energy level ( ${Er}^{3 +} : {}^{4}{I_{11 / 2}}$ ) were lowered. The residual population did not decrease efficiently in the lower laser energy level ( ${Er}^{3 +} : {}^{4}{I_{13 / 2}}$ ) as the level has a longer lifetime. Therefore, the laser would oscillate at longer wavelengths.

Figure 9.Optical spectra recorded in the CW regime and $Q$ -switched regime for OC transmission of 3%.

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4. CONCLUSION

In conclusion, we successfully demonstrated the first, to the best of our knowledge, dual-wavelength passively $Q$ -switched ${Er}^{3 +} : {SrF}_{2}$ laser at 2730.5 and 2752.2 nm, with Bi-NSs as the SA. For an absorbed pump power of 1.97 W, a maximum average output power of 226 mW was achieved. The shortest pulse duration of 980 ns was obtained with a repetition rate of 56.2 kHz, corresponding to a single-pulse energy of 4.02 μJ and a peak power of 4.1 W. The results indicate that Bi-NSs, which are affordable and can be easily prepared, exhibit reliable and excellent features as a promising SA for pulse lasers in the mid-infrared region.

Category: Lasers and Laser Optics

Received: Apr. 6, 2018

Accepted: May. 26, 2018

Published Online: Aug. 1, 2018

The Author Email: Jie Liu (jieliu@sdnu.edu.cn)

DOI:10.1364/PRJ.6.000762