Abstract
Liquid metals, which possess the superiority of low cost, shape-reconfigurability, and excellent optoelectronic properties, have been applied in various fields, such as flexible electronics, superconductivity, and coolants. In this paper, high-quality GaInSn liquid nanospheres synthesized by the ultrasonic method are applied for nonlinear optics and laser switches. The saturation absorption property derived from localized surface plasmon resonance at 639 nm is studied based on the open-aperture Z-scan technique, exhibiting a modulation depth of ∼35.5% and a saturation fluence of ∼21.75 mJ/cm2, respectively. The as-prepared GaInSn liquid nanospheres are also successfully utilized as a saturable absorber to achieve a stable Q-switched Pr:YLF laser at 639 nm. The output pulse width can reach ∼280 ns with a pulse repetition rate of ∼174.8 kHz. Our results suggest that GaInSn liquid nanospheres are a candidate material for generating visible laser pulses, which is of great interest for potential applications in visible nonlinear optics.
© 2022 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement
1. Introduction
In the past decade, pulsed visible lasers have been developed rapidly owing to their unique applications in bio-optics, medical therapy, and underwater laser communication, etc [1–4]. Compared with the nonlinear frequency conversion method, lasers achieved by the two-dimension materials as saturable absorbers have advantages of low cost, easy fabrication, compactness, and designability [5–9]. Analogously, the strong interaction between surface plasmon resonance and electric field of the metallic nanomaterials contributes to its remarkably optical properties, making them excellent optical switchers in the visible waveband [10,11]. Indeed, many efforts have been paid to explore the nonlinear saturation absorption properties and their laser applications of various metallic nanomaterials. For example, K.-H. Kim et al. demonstrated an ultrafast nonlinear optical response of Au nanoparticles with the pump-probe technique, showing a short response time of 1.6 ps [12]. In 2015, high-quality Au nanorods were synthesized and successfully utilized in Pr:YLF bulk lasers operating at orange, red, and deep red spectral regions [13]. This distinction was further conducted by Wu et al. in a Pr3+-doped ZBLAN fiber laser generating a pulse width as shortest as 235 ns [14]. Although Au nanomaterials have presented significant properties and satisfied laser application requirements, they are found to be expensive.
More recently, a novel liquid metal nanomaterial, GaInSn, has caught great attention for its excellent properties in various domains such as mechanical actuation, wearable electronics, and cooling of various precision instruments [15–17]. Nevertheless, few studies on its nonlinear optical property were presented. Similar to the characteristics of most zero-dimensional materials, the nonlinear optical properties of GaInSn nanospheres are governed by the excitation of localized surface plasmon resonance (LSPR) as well [18]. It refers to the strong interaction between surface plasma and the incident laser's electric field, which causes polarizability's intensity and outstanding optical characteristics. The amorphous and high ductility of the liquid metal nanomaterials result in plasmonic microcavities of diverse sizes, exhibiting a broader LSPR than those of traditional nanoparticle materials. In order to explore their linear and nonlinear optical effect, some researchers have fabricated liquid metals and applied them in pulsed lasers. For instance, Q-switched lasers using GaInSn nanospheres as a saturable absorber (SA) were both successfully realized at ∼1.3 µm and ∼2 µm, respectively, demonstrating a pulse width of ∼32 ns at ∼1.3 µm and that of ∼510 ns at ∼2 µm [18]. Noting that the strongly enhanced LSPR of metal nanoparticles at optical frequencies makes them perfect absorbers and scatterers of visible light [19–21], which indicate that they could be an ideal SA candidate for optical switches or mode-lockers in the visible wavelength. Therefore, the nonlinear optical properties, including its performance as SAs in visible pulse lasers, need further research.
Herein, high-quality GaInSn liquid nanospheres were synthesized by the ultrasonic method. The saturation absorption property of the as-prepared GaInSn nanospheres at 639 nm was measured through the open-aperture Z-scan technique, presenting a modulation depth of ∼35.5% and a saturation fluence of ∼21.75 mJ/cm2, respectively. After, we used the GaInSn liquid nanospheres based SA for visible ultrafast pulse generation at 639 nm. The shortest pulse width of ∼280 ns with a maximum repetition rate of ∼174.8 kHz was obtained.
2. Characterization of liquid metal GaInSn nanospheres
We utilized the ultrasonic method to fabricate GaInSn nanospheres for the weak bonding force between liquid metal atoms. The fabrication process can be briefly described as follows. First, the three metals were mixed in the proportions of 68.5% Ga, 21.5% In, and 10% Sn and heated for 10 min at 350 °C to form a GaInSn alloy. As shown in Fig. 1(a), the as-prepared liquid GaInSn alloy was stored in the vessel. To comminute it into nanospheres, the GaInSn alloy was subjected to ultrasonic in acetone for about 20 h. The GaInSn nanospheres with nanometer diameter and uniform shape could be received by optimizing the ultrasonic process parameters and multiple precipitations. As described in Fig. 1(b), the morphology of the GaInSn nanospheres was characterized by a scanning electron microscope (SEM). To observe the shape and size of the nanospheres more clearly, a transmission electron microscope (TEM) was applied, and the morphology was displayed in Fig. 1(c). The TEM image showed that the as-prepared GaInSn nanospheres were almost uniformly spherical, and the corresponding size distribution was illustrated in Fig. 1(d).
Furthermore, the open-aperture Z-scan technique was employed to explore the nonlinear saturation absorption property of the as-prepared GaInSn nanospheres at 639 nm. The laser source was a femtosecond laser with a pulse duration of ∼120 fs and a repetition rate of 5 kHz, respectively. Figure 2(a) displays a measurement result of the normalized nonlinear transmittance at 639 nm. The transmittance increased with the incident laser intensity exhibiting a strong saturation absorption behavior of the GaInSn liquid nanospheres. Generally, the nonlinear transmittance can be written as the following formula:
3. Experimental setup
Figure 3 shows the schematic diagram of the GaInSn nanospheres Q-switched laser. A 3×3×5 mm3 Pr:YLF crystal with a doped concentration of 0.5 at.% was selected as the gain medium, and both end surfaces of the crystal were polished adequately. To reduce the thermal lensing effect, the crystal was wrapped with an indium foil and mounted in a copper with the temperature-controlled at ∼12.3 °C. The pump source was a fiber-coupled GaN blue laser diode (LD) with a central wavelength of 442 nm and a core diameter of 200 µm. The pump light from the LD is focused on the crystal through a planoconvex lens with a focal length of 50 mm. The input mirror (IM) was a plano-plane mirror with anti-reflection coated at 442 nm and high reflection coated at 639 nm. The output couplers (OCs) had a curvature radius of R=-50 mm at different transmittances at 639 nm (0.5%, 1.5%, and 5% are available). Furthermore, to remove the undepleted pump light, an optical filter was put behind the OCs.
By using OCs with different transmittances, the continuous-wave (CW) laser operation was demonstrated first. The absorption efficiency of the 0.5 at.% Pr:YLF crystal at 442 nm was measured to be about 80.5% to calculate the absorbed pump power in our measurement. Figure 4(a) demonstrates the average output powers with the absorbed pump power at different transmittances under the CW laser operation. Under the maximum absorbed pump power of ∼3.6 W, a maximum average output power of ∼730 mW with a slope efficiency of 26.9% was achieved when we used the OC with the output transmittance of 5%.
To explore the saturation absorption property of the GaInSn nanospheres for pulse generation at 639 nm, the as-prepared GaInSn nanosphere-based SA was inserted into the laser cavity and placed closely behind the Pr:YLF crystal. After optimizing the cavity parameters, the passively Q-switched (PQS) laser was realized. As presented in Fig. 4(b), the output power of the Q-switched laser increased monotonously with the absorbed pump power. The maximum output power was ∼45.5 mW under the maximum absorbed pump power of 3.6 W at the transmittance of T = 5%.
The laser output spectra of the CW and PQS operations are exhibited in Fig. 5. We typically observed laser oscillation at 2 different wavelengths: one is at 639 nm, and another one is at 720 nm. It was obvious that the mode oscillation intensity of the 720 nm tended to weaken in the PQS laser for T = 0.5%. This can be explained as follows. The transmittance at 720 nm of the above-mentioned OC was 1.2%. Therefore, the output intensity at 720 nm is higher than that at 639 nm owing to the higher transmittance at 720 nm. When the GaInSn nanosphere-based SA was inserted into the laser cavity, the cavity loss at 720 nm increased. The laser mode of 639 nm was at a superior position in the mode comparison with 720 nm owing to its larger emission cross-section of the Pr:YLF crystal (σ639 nm = 2.18×10−19 cm2; σ720 nm = 8.8×10−20 cm2).
The laser pulse characteristics were detected by a Si detector (DET025A/M, 2 GHz bandwidth, 400 to 1100 nm wavelength range) and synchronously displayed on a digital oscilloscope (RTO 2012, 1 GHz bandwidth, 10 Gs s−1 sampling rates). Figures 6(a), 6(b), and 6(c) depict the pulse durations and repetition rates versus the absorbed pump power at different transmittances of the OCs, respectively. With the transmittance of T = 0.5%, the pulse repetition rate increased almost linearly from ∼123.3 to 174.8 kHz, while the pulse duration decreased from 480 ns to 280 ns. The shortest pulse duration of 280 ns and the maximum repetition frequency of ∼174.8 kHz were achieved. When transmittance of T = 5% was used, the pulse width varied from ∼560 to 360 ns, and the repetition rates presented the variations of ∼79.87-121.9 kHz with the increase of the absorbed pump power from ∼2.2 to 3.6 W.
According to the equations of E = PA/f and PP = E/t, where PA, f, and t were separately average output power, repetition rate, and pulse width, the single pulse energy (E) and peak power (PP) could be calculated. The pulse energy and peak power as a function of the absorbed pump power were recorded at T = 0.5%, 1.5%, and 5% transmittances are shown in Fig. 6(d), 6(e), and 6(f). Under the maximum absorbed pump power of 3.6 W, the maximum single pulse energy was 74.9 nJ at T = 0.5%, 88.2 nJ at T = 1.5%, and 373.3 nJ at T = 5%, respectively, corresponding to the maximum peak power were 267.7 mW, 314.9 mW, and 1036.8 mW. Figure 7 demonstrates the typical single pulse profile and temporal pulse trains indicating a stable operation of the PQS laser.
4. Conclusion
In conclusion, high-quality GaInSn liquid nanospheres were successfully fabricated by the ultrasonic method. The nonlinear optical property was explored through the open-aperture Z-scan technique, presenting a modulation depth of 35.5% and a saturation fluence of ∼21.75 mJ/cm2 at 639 nm, respectively. The as-prepared GaInSn nanospheres were successfully applied as a saturable absorber to achieve a stable Q-switching Pr:YLF laser operation with the shortest pulse width of 280 ns and the highest pulse repetition rate of 174.8 kHz. The results of this work demonstrate the great potential of GaInSn nanospheres in visible nonlinear optics.
Funding
National Key Research and Development Program of China (2019YFA0705000); National Natural Science Foundation of China (62175133); Natural Science Foundation of Shandong Province (ZR2020MF115); Shandong University of Science and Technology (2019TDJH103, skr21-3-049).
Disclosures
There are no conflicts to declare.
Data availability
The data that support the plots and maps within this paper and other findings of this study are available from the corresponding authors upon reasonable request.
References
1. B. Xu, Z. Liu, H. Xu, Z. Cai, C. Zeng, S. Huang, Y. Yan, F. Wang, P. Camy, J. L. Doualan, A. Braud, and R. Moncorgé, “Highly efficient InGaN-LD-pumped bulk Pr:YLF orange laser at 607 nm,” Opt. Commun. 305, 96–99 (2013). [CrossRef]
2. S. Calvez, J. E. Hastie, M. Guina, O. G. Okhotnikov, and M. D. Dawson, “Semiconductor disk lasers for the generation of visible and ultraviolet radiation,” Laser Photonics Rev. 3(5), 407–434 (2009). [CrossRef]
3. P. J. Campagnola and L. M. Loew, “Second-harmonic imaging microscopy for visualizing biomolecular arrays in cells, tissues and organisms,” Nat. Biotechnol. 21(11), 1356–1360 (2003). [CrossRef]
4. K. V. Chellappan, E. Erden, and H. Urey, “Laser-based displays: a review,” Appl. Opt. 49(25), F79–98 (2010). [CrossRef]
5. Z. Luo, D. Wu, B. Xu, H. Xu, Z. Cai, J. Peng, J. Weng, S. Xu, C. Zhu, F. Wang, Z. Sun, and H. Zhang, “Two-dimensional material-based saturable absorbers: towards compact visible-wavelength all-fiber pulsed lasers,” Nanoscale 8(2), 1066–1072 (2016). [CrossRef]
6. Y. Zhong, Z. Cai, D. Wu, Y. Cheng, J. Peng, J. Weng, Z. Luo, B. Xu, and H. Xu, “Passively Q -switched red Pr3+-doped fiber laser with graphene-oxide saturable absorber,” IEEE Photonics Technol. Lett. 28(16), 1755–1758 (2016). [CrossRef]
7. R. Zhang, Y. Zhang, H. Yu, H. Zhang, R. Yang, B. Yang, Z. Liu, and J. Wang, “Broadband black phosphorus optical modulator in the spectral range from visible to mid-infrared,” Adv. Opt. Mater. 3(12), 1787–1792 (2015). [CrossRef]
8. S. Liu, N. Cui, S. Liu, P. Wang, L. Dong, B. Chen, N. Zhang, K. Zhang, and Y. Wang, “Nonlinear optical properties and passively Q-switched laser application of a layered molybdenum carbide at 639 nm,” Opt. Lett. 47(7), 1830–1833 (2022). [CrossRef]
9. N. Cui, F. Zhang, Y. Zhao, Y. Yao, Q. Wang, L. Dong, H. Zhang, S. Liu, J. Xu, and H. Zhang, “The visible nonlinear optical properties and passively Q-switched laser application of a layered PtSe2 material,” Nanoscale 12(2), 1061–1066 (2020). [CrossRef]
10. H. Baida, D. Mongin, D. Christofilos, G. Bachelier, A. Crut, P. Maioli, N. Del Fatti, and F. Vallée, “Ultrafast nonlinear optical response of a single gold nanorod near its surface plasmon resonance,” Phys. Rev. Lett. 107(5), 057402 (2011). [CrossRef]
11. K.-H. Kim, U. Griebner, and J. Herrmann, “Theory of passive mode-locking of semiconductor disk lasers in the blue spectral range by metal nanocomposites,” Opt. Express 20(15), 16174–16179 (2012). [CrossRef]
12. K.-H. Kim, U. Griebner, and J. Herrmann, “Theory of passive mode locking of solid-state lasers using metal nanocomposites as slow saturable absorbers,” Opt. Lett. 37(9), 1490–1492 (2012). [CrossRef]
13. S. Wang, Y. Zhang, J. Xing, X. Liu, H. Yu, A. Di Lieto, M. Tonelli, T. C. Sum, H. Zhang, and Q. Xiong, “Nonlinear optical response of Au nanorods for broadband pulse modulation in bulk visible lasers,” Appl. Phys. Lett. 107(16), 161103 (2015). [CrossRef]
14. D. Wu, J. Peng, Z. Cai, J. Weng, Z. Luo, N. Chen, and H. Xu, “Gold nanoparticles as a saturable absorber for visible 635 nm Q-switched pulse generation,” Opt. Express 23(18), 24071–24076 (2015). [CrossRef]
15. A. Zavabeti, T. Daeneke, A. F. Chrimes, A. P. O’Mullane, J. Zhen Ou, A. Mitchell, K. Khoshmanesh, and K. Kalantar-zadeh, “Ionic imbalance induced self-propulsion of liquid metals,” Nat. Commun. 7(1), 12402 (2016). [CrossRef]
16. M. Ou, W. Qiu, K. Huang, H. Feng, and S. Chu, “Ultrastretchable liquid metal electrical conductors built-in cloth fiber networks for wearable electronics,” ACS Appl. Mater. Interfaces 12(6), 7673–7678 (2020). [CrossRef]
17. Y. Liu, H. F. Chen, H. W. Zhang, and Y. X. Li, “Heat transfer performance of lotus-type porous copper heat sink with liquid GaInSn coolant,” Int. J. Heat Mass Transfer 80, 605–613 (2015). [CrossRef]
18. T. Zhang, M. Wang, Y. Xue, J. Xu, Z. Xie, and S. Zhu, “Liquid metal as a broadband saturable absorber for passively Q-switched lasers,” Chin. Opt. Lett. 18(11), 111901 (2020). [CrossRef]
19. S. Link and M. A. El-Sayed, “Size and temperature dependence of the plasmon absorption of colloidal gold nanoparticles,” J. Phys. Chem. B 103(21), 4212–4217 (1999). [CrossRef]
20. C. Clarke, D. Liu, F. Wang, Y. Liu, C. Chen, C. Ton-That, X. Xu, and D. Jin, “Large-scale dewetting assembly of gold nanoparticles for plasmonic enhanced upconversion nanoparticles,” Nanoscale 10(14), 6270–6276 (2018). [CrossRef]
21. G. Ma, W. Sun, S. H. Tang, H. Zhang, and Z. Shen, “Size and dielectric dependence of the third-order nonlinear optical response of Au nanocrystals embedded in matrices,” Opt. Lett. 27(12), 1043–1045 (2002). [CrossRef]
22. K. Wang, B. M. Szydlowska, G. Wang, X. Zhang, J. J. Wang, J. J. Magan, L. Zhang, J. N. Coleman, J. Wang, and W. J. Blau, “Ultrafast nonlinear excitation dynamics of black phosphorus nanosheets from visible to mid-infrared,” ACS Nano 10(7), 6923–6932 (2016). [CrossRef]
23. Z. Liu, Y. Wang, X. Zhang, Y. Xu, Y. Chen, and J. Tian, “Nonlinear optical properties of graphene oxide in nanosecond and picosecond regimes,” Appl. Phys. Lett. 94(2), 021902 (2009). [CrossRef]