Hostname: page-component-78c5997874-g7gxr Total loading time: 0 Render date: 2024-11-08T04:24:29.022Z Has data issue: false hasContentIssue false

Power-scalable sub-100-fs Tm laser at 2.08 μm

Published online by Cambridge University Press:  23 September 2021

Li Wang
Affiliation:
Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy, 12489 Berlin, Germany
Weidong Chen
Affiliation:
Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy, 12489 Berlin, Germany
Yongguang Zhao*
Affiliation:
Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy, 12489 Berlin, Germany Jiangsu Key Laboratory of Advanced Laser Materials and Devices, School of Physics and Electronic Engineering, Jiangsu Normal University, Xuzhou 221116, China
Hanlin Yang
Affiliation:
Institute of Chemical Materials, China Academy of Engineering Physics, Mianyang 621900, China Key Laboratory of Advanced Ceramics and Mechanical Technology of Ministry of Education, School of Materials Science and Engineering, Tianjin University, Tianjin 300072, China
Wei Jing
Affiliation:
Institute of Chemical Materials, China Academy of Engineering Physics, Mianyang 621900, China
Zhongben Pan
Affiliation:
Institute of Chemical Materials, China Academy of Engineering Physics, Mianyang 621900, China
Hui Huang
Affiliation:
Institute of Chemical Materials, China Academy of Engineering Physics, Mianyang 621900, China
Jiachen Liu
Affiliation:
Key Laboratory of Advanced Ceramics and Mechanical Technology of Ministry of Education, School of Materials Science and Engineering, Tianjin University, Tianjin 300072, China
Ji Eun Bae
Affiliation:
Department of Physics, Korea Advanced Institute of Science and Technology (KAIST), 34141 Daejeon, Republic of Korea
Fabian Rotermund
Affiliation:
Department of Physics, Korea Advanced Institute of Science and Technology (KAIST), 34141 Daejeon, Republic of Korea
Pavel Loiko
Affiliation:
Centre de Recherche sur les Ions, les Matériaux et la Photonique (CIMAP), UMR 6252 CEA-CNRS-ENSICAEN, Université de Caen, 14050 Caen Cedex 4, France
Xavier Mateos
Affiliation:
Física i Cristal·lografia de Materials i Nanomaterials (FiCMA-FiCNA), Universitat Rovira i Virgili (URV), 43007 Tarragona, Spain
Zhengping Wang
Affiliation:
State Key Laboratory of Crystal Materials and Institute of Crystal Materials, Shandong University, Jinan 250100, China
Xinguang Xu
Affiliation:
State Key Laboratory of Crystal Materials and Institute of Crystal Materials, Shandong University, Jinan 250100, China
Uwe Griebner
Affiliation:
Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy, 12489 Berlin, Germany
Valentin Petrov
Affiliation:
Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy, 12489 Berlin, Germany
*
Correspondence to: Y. Zhao, Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy, 12489 Berlin, Germany. Email: [email protected]

Abstract

We report on a power-scalable sub-100-fs laser in the 2-μm spectral range using a Tm3+-doped ‘mixed’ (Lu,Sc)2O3 sesquioxide ceramic as an active medium. Pulses as short as 58 fs at 2076 nm with an average output power of 114 mW at a pulse repetition rate of approximately 82.9 MHz are generated by employing single-walled carbon nanotubes as a saturable absorber. A higher average power of 350 mW at 2075 nm is obtained at the expense of the pulse duration (65 fs). A maximum average power of 486 mW is achieved for a pulse duration of 98 fs and an optical conversion efficiency of 22.3%, representing the highest value ever reported from sub-100-fs mode-locked Tm lasers.

Type
Letter
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2021. Published by Cambridge University Press in association with Chinese Laser Press

1 Introduction

Sub-100-fs mode-locked (ML) lasers at approximately 2 μm with average powers exceeding 100 mW are attractive for multiple applications, for example, synchronous pumping of optical parametric oscillators (SPOPOs) operating at wavelengths longer than 5 μm[Reference Petrov1], mid-infrared (IR) frequency comb generation[Reference Smolski, Yang, Gorelov, Schunemann and Vodopyanov2], as seed sources for chirped pulse amplification (CPA) laser systems and near-degenerate chirped pulse optical parametric amplification (CPOPA)[Reference Fuji, Ishii, Teisset, Gu, Metzger, Baltuska, Forget, Kaplan, Galvanauskas and Krausz3], for the generation of high harmonics and soft X-rays[Reference Popmintchev, Chen, Popmintchev, Arpin, Brown, Ališauskas, Andriukaitis, Balciunas, Mücke, Pugzlys, Baltuška, Shim, Schrauth, Gaeta, Hernández-García, Plaja, Becker, Jaron-Becker, Murnane and Kapteyn4], transparent materials processing[Reference Gattass and Mazur5].

The attractive thermo-optical and spectroscopic properties of thulium (Tm3+)-doped cubic sesquioxide A 2O3 (where A = Y, Lu, Sc or their combinations) make them ideally suited for generating high-power femtosecond pulses from passively ML solid-state lasers in the 2-μm spectral region. Using a single-layer graphene saturable absorber (SA), an average power of 270 mW with a relatively long pulse duration of 410 fs was achieved from an ML Tm:Lu2O3 ceramic laser[Reference Lagatsky, Sun, Kulmala, Sundaram, Milana, Torrisi, Antipov, Lee, Ahn, Brown, Sibbett and Ferrari6]. A semiconductor saturable absorber mirror (SESAM) ML laser generating 750 mW and 382 fs pulses was described in Ref. [Reference Lagatsky, Antipov and Sibbett7] using the same material. Watt-level average output power was achieved via Kerr-lens mode-locking (KLM) of a Tm:Sc2O3 crystalline laser at 2115 nm with a pulse duration of 298 fs[Reference Tokurakawa, Fujita and Kränkel8]. Note that in all these studies, the relatively narrow gain bandwidths of the simple sesquioxides did not support sub-100-fs pulse generation.

Tm3+-doped ‘mixed’ sesquioxides (A,B)2O3 with compositional disorder inducing inhomogeneous broadening of the absorption and gain spectra are obviously advantageous in the sub-100-fs regime at 2 μm[Reference Kränkel9Reference Stevenson, Brown, Hopkins, Dawson, Kränkel and Lagatsky11]. Compared with crystalline sesquioxides, transparent ceramics offer more flexibility owing to the less-challenging fabrication process. The latter features size scalability, overcoming temperature limits of the crystal growth (very high crystal melting temperatures, typically ~2400°C–2500°C) and the potential for creating controlled ‘mixed’ compositions with a specific doping level[Reference Vetrovec, Filgas, Smith, Copeland, Litt, Briscoe and Schirmer12, Reference Jing, Loiko, Serres, Wang, Vilejshikova, Aguiló, Díaz, Griebner, Huang, Petrov and Mateos13]. High-quality, almost pore-free Tm3+-doped ‘mixed’ polycrystalline sesquioxides, for example Tm:(Lu,Sc)2O3 and Tm:(Lu,Y)2O3, are fabricated by the hot isostatic pressing (HIP) sintering method[Reference Jing, Loiko, Serres, Wang, Vilejshikova, Aguiló, Díaz, Griebner, Huang, Petrov and Mateos13, Reference Zhou, Guan, Huang, Xu, Xu, Cai, Xu, Liu, Li, Zhang and Xu14]. Sub-100-fs ML operation of such a Tm3+-doped ‘mixed’ ceramic laser was first demonstrated in 2018: 63-fs pulses with an average power of only 34 mW were generated at 2057.2 nm employing a SESAM[Reference Wang, Jing, Loiko, Zhao, Huang, Mateos, Suomalainen, Härkönen, Guina, Griebner and Petrov15]. Subsequently, shorter pulse durations of 57 fs at 2045 nm and 54 fs at 2048 nm were reported using a single-walled carbon nanotube (SWCNT)-based SA and a SESAM, respectively, with average output power still below 100 mW[Reference Zhao, Wang, Wang, Zhang, Liu, Xu, Liu, Shen, Bae, Park, Rotermund, Mateos, Loiko, Wang, Xu, Xu, Mero, Griebner, Petrov and Chen16, Reference Zhao, Wang, Chen, Pan, Wang, Liu, Xu, Liu, Shen, Zhang, Guina, Mateos, Loiko, Wang, Xu, Xu, Mero, Griebner and Petrov17]. Figure 1 summarizes the state of the art of sub-100-fs ML solid-state Tm lasers emitting in the 2-μm spectral range[Reference Zhao, Wang, Wang, Zhang, Liu, Xu, Liu, Shen, Bae, Park, Rotermund, Mateos, Loiko, Wang, Xu, Xu, Mero, Griebner, Petrov and Chen16Reference Pan, Wang, Zhao, Yuan, Dai, Cai, Bae, Choi, Rotermund, Mateos, Serres, Loiko, Griebner and Petrov22]. An average power of 210 mW was demonstrated in 2019 with an SWCNT-SA ML Tm:LuYO3 ceramic laser[Reference Zhao, Wang, Wang, Zhang, Liu, Xu, Liu, Shen, Bae, Park, Rotermund, Mateos, Loiko, Wang, Xu, Xu, Mero, Griebner, Petrov and Chen16]. In 2020, a slightly higher power of 222 mW was obtained from a Tm:Sc2O3 laser using the KLM technique[Reference Suzuki, Kränkel and Tokurakawa21], which represents the highest power ever reported from such sub-100-fs ML solid-state Tm lasers. One can recognize that all the average powers higher than 100 mW were obtained by using the above-mentioned sesquioxide materials[Reference Zhao, Wang, Wang, Zhang, Liu, Xu, Liu, Shen, Bae, Park, Rotermund, Mateos, Loiko, Wang, Xu, Xu, Mero, Griebner, Petrov and Chen16, Reference Zhao, Wang, Chen, Pan, Wang, Liu, Xu, Liu, Shen, Zhang, Guina, Mateos, Loiko, Wang, Xu, Xu, Mero, Griebner and Petrov17, Reference Suzuki, Kränkel and Tokurakawa21], and an obvious trade-off between average power and pulse duration can be seen from all these reported results.

Figure 1 The state-of-the-art of sub-100-fs ML Tm lasers operating in the 2-μm spectral range (average output power versus pulse duration). The red stars summarize our present results.

The above results and the superior thermo-optical and improved spectroscopic properties of the Tm3+-doped ‘mixed’ polycrystalline sesquioxides motivated us to further explore the feasibility of average power scaling in the sub-100-fs regime. For this purpose, a broadband SA that possesses a low non-saturable loss and high damage threshold at approximately 2 μm is required. Compared with SESAMs, carbon-nanostructure-based SAs, for example graphene[Reference Ugolotti, Schmidt, Petrov, Kim, Yeom, Rotermund, Bae, Hong, Agnesi, Fiebig, Erbert, Mateos, Aguilo, Diaz and Griebner23] and SWCNT SAs[Reference Cho, Yim, Choi, Lee, Schmidt, Steinmeyer, Griebner, Petrov, Yeom, Kim and Rotermund24], exhibit a broader spectral response and are fabricated by simpler and less expensive techniques. Here, we present the performance of a power-scalable SWCNT-SA ML ‘mixed’ Tm:(Lu,Sc)2O3 ceramic laser in the sub-100-fs regime at approximately 2.08 μm.

2 Experimental setup

The high-quality ‘mixed’ Tm:(Lu2/3Sc1/3)2O3 transparent ceramic used in the experiment was fabricated by the HIP sintering method. The Tm3+ doping was 2.8% (atomic fraction) (N Tm = 8.12 × 1020 cm–3). A linear X-folded astigmatically compensated resonator was arranged for evaluating the laser performance both in the continuous-wave (CW) and the ML regimes, as illustrated in Figure 2. An uncoated ceramic sample having a thickness of 3 mm and an aperture of 3 mm× 3 mm was mounted on a copper holder with water cooling (coolant temperature: 12°C) and placed between two dichroic folding mirrors, M1 and M2 (radius of curvature, RoC = –100 mm), with the Brewster minimum loss condition fulfilled for the laser wavelength. The pump source was a narrow-linewidth CW Ti:sapphire laser tuned to 795 nm emitting linearly polarized radiation. The pump beam was focused into the ceramic using a spherical lens having a focal length of 70 mm to form a waist with beam radii of 30 μm and 77 μm in the sagittal and tangential planes, respectively.

Figure 2 Experimental configuration of the CW and ML Tm:(Lu,Sc)2O3 ceramic laser. L, focusing lens; M1 and M2, concave dichroic mirrors; M3, plane rear mirror; DM1–DM4, dispersive mirrors; OC, output coupler.

3 Results

The CW laser performance was investigated with a four-mirror cavity including a plane rear reflector M3 and a plane-wedged output coupler (OC; without the SWCNT-SA); see Figure 3(a). The measured single-pass pump absorption under lasing conditions was between 57.4% and 58.6%, depending slightly on the OC (0.2%–3%). A maximum power of 755 mW was obtained at an absorbed power of 1.84 W for the 1.5% OC, corresponding to a slope efficiency of 43.6%. The round-trip passive loss was estimated using the Caird analysis[Reference Caird, Payne, Staber, Ramponi, Chase and Krupke25], that is, fitting the measured slope efficiency as a function of the OC reflectivity, giving total round-trip resonator losses of δ = 0.21%, as shown in Figure 3(b). The determined value of δ indicates high optical quality of the transparent ceramic and a well-optimized laser resonator.

Figure 3 (a) Laser performance of the Tm:(Lu,Sc)2O3 ceramic laser in the CW regime for different OC transmission T OC. (b) Cavity loss fitting curve with the slope efficiency as a function of the OC reflectivity, R OC = 1 – T OC.

To initiate and stabilize a soliton-like ML operation, a transmission-type SWCNT-SA (relying on the first fundamental electronic transition E11 of semiconducting nanotubes for absorption at ~2 μm[Reference Cho, Yim, Choi, Lee, Schmidt, Steinmeyer, Griebner, Petrov, Yeom, Kim and Rotermund24]) was employed. The nanotubes were synthesized by the arc-discharge method and the SWCNT/poly(methyl methacrylate) (PMMA) film was spin-coated on a 1-mm-thick fused silica (FS) substrate. The SWCNT-SA exhibited a relatively low non-saturable linear loss of approximately 1%, small saturation fluence of less than 10 μJ/cm2, very low modulation depth of less than 0.5% and a slow recovery time constant of approximately 1 ps at approximately 2 μm[Reference Schmidt, Choi, Yeom, Rotermund, Mateos, Segura, Diaz, Petrov and Griebner26]. It was placed at Brewster’s angle in the second cavity beam waist having beam radii of 125 μm and 225 μm in the sagittal and tangential planes, respectively. The latter was created by two concave dispersive mirrors (DMs), DM1 and DM2, with RoC of –100 and –50 mm, respectively. The steady-state soliton-like pulses were generated by varying the number of bounces on the DMs (DM1–DM4) for negative group delay dispersion (GDD) to balance the self-phase modulation (SPM)[Reference Kartner, Jung and Keller27]. All DMs exhibited a GDD of –125 fs2 per bounce. The roundtrip material GDD due to the 3-mm thick ceramic sample amounted to approximately –200 fs2 at 2.08 μm, estimated by averaging the refractive indices of Lu2O3 and Sc2O3[Reference Zelmon, Northridge, Haynes, Perlov and Petermann28]. Additional material GDD of approximately –240 fs2 (per round-trip) was introduced by the FS SA substrate.

In addition to the two concave mirrors DM1 and DM2, two bounces on the flat DMs (DM3 and DM4) were implemented yielding a net round-trip cavity GDD of –875 fs2. The ML laser performance was studied by varying the output coupling without changing the cavity length. The latter corresponded to a pulse repetition rate of approximately 82.9 MHz. When applying the 1.5% OC, a self-starting ML operation was achieved with ultimate stability by careful cavity alignment. The central emission wavelength was 2075 nm with a 72 nm FWHM (full width at half maximum). The measured spectrum with its sech2-shaped fit is shown in Figure 4(a). The recorded fringe-resolved autocorrelation trace leads to a deconvolved pulse duration of 65 fs (FWHM) by assuming a sech2-shaped temporal profile, as shown in Figure 4(b), which was only 3.4% longer than the Fourier-transform limit. The average output power amounted to 350 mW for an absorbed pump power of 2.2 W corresponding to an optical conversion efficiency η opt of 15.9%. The excellent sech2-shaped spectral and temporal profiles indicate soliton ML operation of the Tm:(Lu,Sc)2O3 ceramic laser.

Figure 4 SWCNT-SA ML Tm:(Lu,Sc)2O3 ceramic laser with T OC = 1.5%: (a) measured optical spectrum and (b) interferometric autocorrelation trace.

Further power scaling in the ML regime was achieved by increasing the OC transmission at the expense of the pulse duration. Indeed, using a 3% OC, the average power reached 486 mW at an absorbed pump power of 2.18 W, which corresponded to η opt = 22.3%. Figure 5 shows the measured spectrum and fringe-resolved autocorrelation trace. The pulses had a well-fitted sech2-shaped spectrum with an FWHM of 47 nm at 2086 nm and a temporal FWHM of 98 fs, derived from the autocorrelation trace. Assuming a sech2-shaped temporal profile, the resulting time-bandwidth product (TBP) was 0.317, which is evidence for the generation of soliton pulses with a nearly Fourier-limited duration, as expected from the almost perfect fits both in the spectral and in the temporal domains.

Figure 5 SWCNT-SA ML Tm:(Lu,Sc)2O3 ceramic laser with T OC = 3%: (a) measured optical spectrum and (b) interferometric autocorrelation trace.

The shortest pulses were achieved by reducing the output coupling to 0.5% at the expense of the average power. After extra-cavity linear chirp compensation with a 3-mm-thick polycrystalline ZnS plate (GDD = 465 fs2 at 2.08 μm), the pulses were compressed from 66 to 58 fs (eight optical cycles). The average output power amounted to 114 mW for an absorbed pump power of 2.19 W. The ML laser spectrum with a central wavelength of 2076 nm exhibited a significant spectral broadening compared to operation with 1.5% and 3% OC, owing to relatively strong SPM originating from the Tm:(Lu,Sc)2O3 ceramic, as shown in Figure 6(a). The on-axis intracavity peak intensity on the ceramic sample reached 292 GW/cm2. The pulse duration, which was deconvolved from the measured fringe-resolved autocorrelation trace after compression [see Figure 6(b)], is 20.8% longer than the Fourier-transform limited value of the measured spectrum. We attribute the asymmetric spectral profiles (deviation from the ideal sech2-shaped spectral profile) to the unmanageable intracavity GDD at the long-wave spectral wing, that is, at wavelengths higher than 2.15 μm, and the non-optimized reflection bands of individual cavity mirrors (cf. Figures 4(a) and 6(a)).

Figure 6 SWCNT-SA ML Tm:(Lu,Sc)2O3 ceramic laser with T OC = 0.5%: (a) measured optical spectrum and (b) interferometric autocorrelation trace.

The stability in the ML regime of the laser was confirmed by measurements with a radio frequency (RF) spectrum analyser in two frequency span ranges. The recorded fundamental beat note at 82.94 MHz exhibited a high signal-to-noise ratio (SNR) of more than 75 dBc (see Figure 7(a)). The uniform harmonic beat notes in the 1-GHz frequency span (see Figure 7(b)) are evidence for stable steady-state ML operation without any Q-switching and/or multi-pulsing instabilities.

Figure 7 Radio frequency (RF) spectra of the ML Tm:(Lu,Sc)2O3 ceramic laser with T OC = 0.5%: (a) fundamental beat note and (b) 1-GHz span. RBW, resolution bandwidth.

4 Conclusion

In conclusion, we demonstrated average power scaling of an SWCNT-SA ML ‘mixed’ Tm:(Lu,Sc)2O3 ceramic laser maintaining the sub-100-fs regime near 2 μm. Pulses as short as 58 fs were generated at 2076 nm with an average power of 114 mW and a pulse repetition rate of approximately 82.9 MHz. A maximum average output power as high as 486 mW was directly obtained from the ML laser at 2086 nm for a pulse duration of 98 fs, with a conversion efficiency of 22.3%. This represents the highest average output power and conversion efficiency ever reported from any sub-100-fs ML Tm laser. Given the imperfect design of the cavity mirrors, shorter pulse durations would be possible after optimizing the reflection bands of the cavity mirrors, as well as by fine control of the total intracavity GDD over the full spectral bandwidth of the ML laser.

Acknowledgements

This work was partly supported by the National Natural Science Foundation of China (NSFC) (52032009, 61975208, 62075090, 51761135115, 61575199, 61850410533, and 52072351); Deutsche Forschungsgemeinschaft (PE 607/14-1); Sino-German Scientist Cooperation and Exchanges Mobility Program (M-0040); Natural Science Foundation of Jiangsu Province (BK20190104); National Research Foundation of Korea (2020R1A4A2002828); CAS Key Laboratory of Optoelectronic Materials Chemistry and Physics, FJIRSM CAS (2008DP173016); Foundation of the President of China Academy of Engineering Physics (YZJJLX2018005); State Key Laboratory of Crystal Materials (SKLCM), SDU (KF2001). Yongguang Zhao acknowledges financial support from the Alexander von Humboldt Foundation through a Humboldt fellowship.

References

Petrov, V., Prog. Quantum Electron. 42, 1 (2015).CrossRefGoogle Scholar
Smolski, V. O., Yang, H., Gorelov, S. D., Schunemann, P. G., and Vodopyanov, K. L., Opt. Lett. 41, 1388 (2016).CrossRefGoogle Scholar
Fuji, T., Ishii, N., Teisset, C. Y., Gu, X., Metzger, T., Baltuska, A., Forget, N., Kaplan, D., Galvanauskas, A., and Krausz, F., Opt. Lett. 31, 1103 (2006).CrossRefGoogle Scholar
Popmintchev, T., Chen, M., Popmintchev, D., Arpin, P., Brown, S., Ališauskas, S., Andriukaitis, G., Balciunas, T., Mücke, O. D., Pugzlys, A., Baltuška, A., Shim, B., Schrauth, S. E., Gaeta, A., Hernández-García, C., Plaja, L., Becker, A., Jaron-Becker, A., Murnane, M. M., and Kapteyn, H. C., Science 336, 1287 (2012).CrossRefGoogle Scholar
Gattass, R. R. and Mazur, E., Nat. Photonics 2, 219 (2008).CrossRefGoogle Scholar
Lagatsky, A. A., Sun, Z., Kulmala, T. S., Sundaram, R. S., Milana, S., Torrisi, F., Antipov, O. L., Lee, Y., Ahn, J. H., Brown, C. T. A., Sibbett, W., and Ferrari, A. C., Appl. Phys. Lett. 102, 013113 (2013).CrossRefGoogle Scholar
Lagatsky, A. A., Antipov, O. L., and Sibbett, W., Opt. Express 20, 19349 (2012).CrossRefGoogle Scholar
Tokurakawa, M., Fujita, E., and Kränkel, C., Opt. Lett. 42, 3185 (2017).CrossRefGoogle Scholar
Kränkel, C., IEEE J. Sel. Top. Quantum Electron. 21, 1602013 (2015).CrossRefGoogle Scholar
Stevenson, N. K., Brown, C. T. A., Hopkins, J. M., Dawson, M. D., and Lagatsky, A. A., Opt. Express 27, 11103 (2019).CrossRefGoogle Scholar
Stevenson, N. K., Brown, C. T. A., Hopkins, J. M., Dawson, M. D., Kränkel, C., and Lagatsky, A. A., Opt. Lett. 43, 1287 (2018).CrossRefGoogle Scholar
Vetrovec, J., Filgas, D. M., Smith, C. A., Copeland, D. A., Litt, A. S., Briscoe, E., and Schirmer, E., Proc. SPIE 10511, 1051103 (2018).Google Scholar
Jing, W., Loiko, P., Serres, J. M., Wang, Y., Vilejshikova, E., Aguiló, M., Díaz, F., Griebner, U., Huang, H., Petrov, V., and Mateos, X., Opt. Mater. Express 7, 4192 (2017).CrossRefGoogle Scholar
Zhou, Z. Y., Guan, X. F., Huang, X. X., Xu, B., Xu, H. Y., Cai, Z. P., Xu, X. D., Liu, P., Li, D. Z., Zhang, J., and Xu, J., Opt. Lett. 42, 3781 (2017).CrossRefGoogle Scholar
Wang, Y., Jing, W., Loiko, P., Zhao, Y., Huang, H., Mateos, X., Suomalainen, S., Härkönen, A., Guina, M., Griebner, U., and Petrov, V., Opt. Express 26, 10299 (2018).CrossRefGoogle Scholar
Zhao, Y., Wang, L., Wang, Y., Zhang, J., Liu, P., Xu, X., Liu, Y., Shen, D., Bae, J. E., Park, T. G., Rotermund, F., Mateos, X., Loiko, P., Wang, Z., Xu, X., Xu, J., Mero, M., Griebner, U., Petrov, V., and Chen, W., Opt. Lett. 45, 459 (2020).CrossRefGoogle Scholar
Zhao, Y., Wang, L., Chen, W., Pan, Z., Wang, Y., Liu, P., Xu, X., Liu, Y., Shen, D., Zhang, J., Guina, M., Mateos, X., Loiko, P., Wang, Z., Xu, X., Xu, J., Mero, M., Griebner, U., and Petrov, V., Appl. Opt. 59, 10493 (2020).CrossRefGoogle Scholar
Wang, Y. C., Chen, W. D., Mero, M., Zhang, L. Z., Lin, H. F., Lin, Z. B., Zhang, G., Rotermund, F., Cho, Y. J., Loiko, P., Mateos, X., Griebner, U., and Petrov, V., Opt. Lett. 42, 3076 (2017).CrossRefGoogle Scholar
Wang, L., Chen, W., Zhao, Y., Wang, Y., Pan, Z., Lin, H., Zhang, G., Zhang, L., Lin, Z., and Bae, J., Opt. Lett. 45, 6142 (2020).CrossRefGoogle Scholar
Wang, Y., Zhao, Y., Pan, Z., Bae, J. E., Choi, S. Y., Rotermund, F., Loiko, P., Serres, J. M., Mateos, X., Yu, H., Zhang, H., Mero, M., Griebner, U., and Petrov, V., Opt. Lett. 43, 4268 (2018).CrossRefGoogle Scholar
Suzuki, A., Kränkel, C., and Tokurakawa, M., Appl. Phys. Express 13, 052007 (2020).CrossRefGoogle Scholar
Pan, Z., Wang, Y., Zhao, Y., Yuan, H., Dai, X., Cai, H., Bae, J. E., Choi, S. Y., Rotermund, F., Mateos, X., Serres, J. M., Loiko, P., Griebner, U., and Petrov, V., Photon. Res. 6, 800 (2018).CrossRefGoogle Scholar
Ugolotti, E., Schmidt, A., Petrov, V., Kim, J. W., Yeom, D. I., Rotermund, F., Bae, S., Hong, B. H., Agnesi, A., Fiebig, C., Erbert, G., Mateos, X., Aguilo, M., Diaz, F., and Griebner, U., Appl. Phys. Lett. 101, 161112 (2012).CrossRefGoogle Scholar
Cho, W. B., Yim, J. H., Choi, S. Y., Lee, S., Schmidt, A., Steinmeyer, G., Griebner, U., Petrov, V., Yeom, D. I., Kim, K., and Rotermund, F., Adv. Funct. Mater. 20, 1937 (2010).CrossRefGoogle Scholar
Caird, J. A., Payne, S. A., Staber, P., Ramponi, A., Chase, L., and Krupke, W. F., IEEE J. Quantum. Electron. 24, 1077 (1988).CrossRefGoogle Scholar
Schmidt, A., Choi, S. Y., Yeom, D. I., Rotermund, F., Mateos, X., Segura, M., Diaz, F., Petrov, V., and Griebner, U., Appl. Phys. Express 5, 092704 (2012).CrossRefGoogle Scholar
Kartner, F., Jung, I., and Keller, U., IEEE J. Sel. Top. Quantum Electron. 2, 540 (1996).CrossRefGoogle Scholar
Zelmon, D. E., Northridge, J. M., Haynes, N. D., Perlov, D., and Petermann, K., Appl. Opt. 52, 3824 (2013).CrossRefGoogle Scholar
Figure 0

Figure 1 The state-of-the-art of sub-100-fs ML Tm lasers operating in the 2-μm spectral range (average output power versus pulse duration). The red stars summarize our present results.

Figure 1

Figure 2 Experimental configuration of the CW and ML Tm:(Lu,Sc)2O3 ceramic laser. L, focusing lens; M1 and M2, concave dichroic mirrors; M3, plane rear mirror; DM1–DM4, dispersive mirrors; OC, output coupler.

Figure 2

Figure 3 (a) Laser performance of the Tm:(Lu,Sc)2O3 ceramic laser in the CW regime for different OC transmission TOC. (b) Cavity loss fitting curve with the slope efficiency as a function of the OC reflectivity, ROC = 1 – TOC.

Figure 3

Figure 4 SWCNT-SA ML Tm:(Lu,Sc)2O3 ceramic laser with TOC = 1.5%: (a) measured optical spectrum and (b) interferometric autocorrelation trace.

Figure 4

Figure 5 SWCNT-SA ML Tm:(Lu,Sc)2O3 ceramic laser with TOC = 3%: (a) measured optical spectrum and (b) interferometric autocorrelation trace.

Figure 5

Figure 6 SWCNT-SA ML Tm:(Lu,Sc)2O3 ceramic laser with TOC = 0.5%: (a) measured optical spectrum and (b) interferometric autocorrelation trace.

Figure 6

Figure 7 Radio frequency (RF) spectra of the ML Tm:(Lu,Sc)2O3 ceramic laser with TOC = 0.5%: (a) fundamental beat note and (b) 1-GHz span. RBW, resolution bandwidth.