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Photonic crystal rod-based high-performance ultrafast fiber laser system

Published online by Cambridge University Press:  01 December 2020

Zhiguo Lv*
Affiliation:
School of Physical Science and Technology, Inner Mongolia Key Laboratory of Nanoscience and Nanotechnology, Inner Mongolia University, Hohhot 010021, China
Zhi Yang
Affiliation:
State Key Laboratory of Transient Optics and Photonics, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an 710119, China
Qianglong Li
Affiliation:
State Key Laboratory of Transient Optics and Photonics, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an 710119, China
Feng Li
Affiliation:
State Key Laboratory of Transient Optics and Photonics, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an 710119, China
Yishan Wang
Affiliation:
State Key Laboratory of Transient Optics and Photonics, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an 710119, China
Wei Zhao
Affiliation:
State Key Laboratory of Transient Optics and Photonics, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an 710119, China
Xiaojun Yang*
Affiliation:
State Key Laboratory of Transient Optics and Photonics, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an 710119, China
*
Correspondence to: Zhiguo Lv, School of Physical Science and Technology, Inner Mongolia University, Hohhot 010021, China; Xiaojun Yang, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an 710119, China. Email: [email protected] (Z. Lv); [email protected] (X. Yang)
Correspondence to: Zhiguo Lv, School of Physical Science and Technology, Inner Mongolia University, Hohhot 010021, China; Xiaojun Yang, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an 710119, China. Email: [email protected] (Z. Lv); [email protected] (X. Yang)

Abstract

In this paper, we innovatively conduct a Porro prism-based beam pointing stability promotion technique research and realize a high-performance rod-type photonic crystal fiber-based chirped pulse amplification (CPA) system, mainly including a frequency-reduced all-fiber pre-amplification stage, photonic crystal rod-based main amplification stage, and 1600 lines/mm transmission grating-pair compressor. Laser output with average power of 50 W, repetition rates of 500 kHz, pulse energy of 100 μJ, pulse duration of 830 fs, beam quality of M2<1.3, power fluctuation of 0.55% root mean square, and beam pointing drift of 19 μrad/°C over 8 h is realized. The high-performance laser system has an enormous application potential in fundamental research and precision manufacturing fields.

Type
Research Article
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 (http://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), 2020. Published by Cambridge University Press in association with Chinese Laser Press

1 Introduction

In the last few years, ultrafast laser systems have foundunprecedented application success in numerous fields of science and industry, e.g., atto-second science, strong-field physics, bio-photonics, and automotive and aerospace machining fields[ 1–5 ]. For now, most of the femtosecond lasers in practical use are configured in chirped pulse amplification (CPA) architectures based on bulk solid-state crystals or flexible gain fibers. The conventional bulk solid-state laser systems have advantages in achieving pulses with high peak power[ 6–8 ] and short pulse duration[ Reference Tian, Yu, Zhu, Zhang, Wei, Xu and Xu 9 ]. However, they are also restricted in repetition rate and average power owing to thermo-optical effect induced beam distortion[ 10–12 ].

To increase pumping capacity and simultaneously weaken nonlinear effects, single-crystal fiber (SCF) amplifiers have been constructed and demonstrated strong potential for generating pulses with high energy[ Reference Délen, Zaouter, Martial, Aubry, Didierjean, Mottay, Balembois and Georges 13 , Reference Veselis, Bartulevicius, Madeikis, Michailovas and Rusteika 14 ] and allowing hundreds of average power laser outputs[ Reference Markovic, Rohrbacher, Hofmann, Pallmann, Pierrot and Resan 15 ]. However, in the femtosecond regime, owing to narrow amplification bandwidth and high quantum defect, the efficient femtosecond SCF amplifiers are less convenient to be implemented compared with other ytterbium (Yb)-doped gain media[ Reference Lesparre, Gomes, Délen, Martial, Didierjean, Pallmann, Resan, Druon, Balembois and Georges 16 ].

In contrast with conventional bulk solid–state counterparts and SCFs, Yb-doped gain fibers offer a more efficient pumping scheme, diffraction limited beam quality, and broader gain bandwidth[ Reference Chénais, Druon, Forget, Balembois and Georges 17 , Reference Lv, Teng, Wang, Wang, Wang and Wei 18 ]. First, fiber lasers offer a lot of practical advantages over conventional solid-state counterparts, such as reduced alignment sensitivity, compact size, and low cost. In addition, benefiting from the high-power cladding-pumping technique, large single-pass gain characteristic, and flexible propagation route, fiber lasers are acknowledged as one of the most promising and practical powerful tools in numerous application fields. Second, thermal-induced beam distortion is reduced under the high-power pumping condition because of the high surface-to-volume ratio of the fiber geometry, and as a result, excellent spatial mode quality is guaranteed because of the intrinsic waveguide properties. However, amplification of pulses in fiber amplifiers is subjected to low-nonlinearity threshold limitation (such as self-phase modulation, Raman scattering)[ Reference Kalaycioglu, Oktem, Şenel, Paltani and Ilday 19 , Reference Fernández, Zhu, Verhoef, Biryukov, Pugzlys, Galvabauskas, Ilday and Baltuška 20 ]. Both effects induce pulse fidelity degradation in the time domain and energy transfer in the spectral regime. In ultrafast optics, stretching seed pulses before amplification and recompressing pulses after amplification are common ways to scale the pulse power and energy. In addition, there is also another approach to weaken the nonlinear effects of fiber, and at the same time enlarge the power and energy of femtosecond pulses, that is, to increase the fiber mode field area (MFA) in combination with the use of a relatively short gain section. Yb-doped gain fibers provide efficient pumping at 976 nm and at least 15 dB/m cladding absorption. Therefore, femtosecond fiber optics amplification systems allow for relatively short gain fiber design to reduce nonlinearity to some extent. The most successful attempt of MFA increment is the development and use of rod-type photonic crystal fibers. Exceptional performances in terms of average power and pulse energy have been demonstrated using photonic crystal rod[ 21–24 ].

In addition to the excellent beam quality and clean pulse quality, in industrial-scale precision material processing, beam pointing stability of ultrafast fiber laser systems is also crucial. There are some key factors that can worsen beam pointing stability, such as structure deformation induced by heat stress and beam offset introduced by reflective mirrors used in the compressor. Such factors can significantly degrade machining quality and even render the laser cannot be used in practical precision manufacturing, especially for taper-controlled micro-hole manufacturing with tens of micrometer aperture in automotive and aerospace fields. Without adopting any control technique, the general beam pointing stability can be at least ~100 μrad/°C or worse. Therefore, efficient heat dissipation in combination with compact insensitive compressor architecture design is crucial for improving beam pointing stability. However, most of the research literature on rod-type fiber femtosecond amplifiers aimed at scaling average power and improving pulse energy, at the same time reducing nonlinear effects and obtaining ultrashort pulse duration. However, research into improving beam pointing stability has been rarely mentioned, such as in Refs. [21–24]. As a result, in order to meet the critical requirements of practical application, in femtosecond CPA laser systems with large dispersion manipulation, how to reasonably design and integrate the optical route of the compressor and simultaneously ensure the promotion of beam pointing stability remains an important research subject and of great significance.

In contrast with the previous reported experimental research on rod-fiber ultrafast laser systems[ 21–24 ], in our work, in addition to the general concerned average power, pulse energy, and pulse duration, we have also directed our research towards a beam pointing stability promotion technique. Therefore, we innovatively implemented a research work on improving beam pointing stability performance of high-power femtosecond fiber CPA laser systems, and presented a photonic crystal rod-based high-performance femtosecond fiber CPA laser source. Through the design of a Porro prism (PP)-based folded optical path in the compressor, a maximum pointing drift of 19 μrad/°C over 8 h is obtained. Not only do we realize system integration, such a design of PP-based folded optical route also significantly improves the beam pointing stability of the presented femtosecond fiber CPA laser system. The previously mentioned beam pointing drift of 19 μrad/°C meets most of the application requirements of micro-hole manufacturing with tens of micrometer aperture, and is significant. Herein, in addition to the excellent beam pointing stability (19 μrad/°C over 8 h), the presented high-performance femtosecond fiber laser system also has more than 50 W average power, pulse energy of 100 μJ, and power fluctuation of 0.55% root mean square (RMS) over 8 h, parameters sufficient to process most hard and fragile materials. Therefore, the presented femtosecond laser system has important practical value in use, and the laser performance defined by these laser parameters can significantly promote the improvement of machining accuracy and quality of materials.

2 Experimental setup

The experimental setup for the proposed photonic crystal rod-based high-performance femtosecond fiber CPA laser system is schematically shown in Figure 1. The laser configuration mainly consists of a home-made SESAM mode-locked fiber oscillator, a chirped fiber Bragg grating (CFBG), the first pre-amplification stage, an acousto-optic modulator (AOM), the second pre-amplification stage, photonic crystal rod-based main amplification stage, as well as a PP-based transmission grating-pair compressor.

Figure 1 Schematic of the photonic crystal rod-based femtosecond fiber CPA laser system. WDM, wavelength division multiplexer; PD-ISO, polarization-dependent optical isolator; AOM, acousto-optic modulator; CFBG, chirped fiber Bragg grating; HWP, half-wave plate; HR, highly reflective mirror; L1, L2, L3, lens with 30 mm, 60 mm, and 20 mm focal length, respectively.

The previously mentioned home-made seed source delivers pulses with 34.56 MHz repetition rates and power around 5 mW. The central wavelength lies in 1032.5 nm with 13.7 nm spectral bandwidths. This laser provides sufficient signal for the following temporal stretching and power amplification.

For the first pre-amplification stage, concretely speaking, it consists of a core-pumped preamplifier and a cladding-pumped power amplifier. The core-pumped preamplifier has 0.75-m-long Yb-doped gain fiber (Nufern, PM-YSF-HI-HP) and is pumped forward under the pump power of 120 mW. The cladding-pumped power amplifier has 1.2-m-long double-clad (DC) Yb-fiber with 10 μm core diameter and 125 μm cladding diameter (Nufern, PLMA-YDF-10/125-M). In experiments, multimode pump power is coupled into the cladding of the DC Yb-doped fiber through a PM (2+1)×1 pump combiner. The combiner has the same input and output fibers with core/cladding diameter of 10 μm/125 μm.

In the second pre-amplification stage, in addition to the 0.6-m-long DC Yb-fiber preamplifier (of the same fiber type as in the first pre-amplification stage), 1.15-m-long large-mode-area (LMA) DC Yb-fiber with core/cladding diameter of 35 μm/250 μm (Yb MCOF-35/250-PM) is also employed for further power scaling and energy enhancement. In this stage, two 976 nm laser diodes with maximum 9 W and 27.5 W average power are used as pump sources. Pump power is delivered into the LMA DC fiber through a (2+1)×1 PM pump combiner with 10 μm/125 μm input fiber and 25 μm/250 μm output fiber.

In the main amplification stage, considering the energy-dependent nonlinearity, LMA rod-type photonic crystal fiber (NKT, aeroGain-Rod-PM85) is used to weaken the nonlinearity in gain medium as much as possible. The photonic crystal rod has 0.8 m length and 15 dB cladding absorption at 976 nm. The core diameter and cladding diameter are 85 μm and 260 μm, respectively. For pumping, a high-power fiber-coupled laser diode is used as the drive source and up to 250 W continuous wave (CW) power can be emitted. The pump laser from the fiber-coupled laser diode is straight coupled into the photonic crystal rod via an aspherical lens with 20 mm focal length after being collimated. The collimating aspherical lens has 30 mm focal length. In experiment, in order to protect the high-power laser diode from damage introduced by the reverse transmitted amplified laser pulses, two orthogonally positioned dichroic mirrors with 99.5% reflection at 1020–1080 nm and 94.4% transmission at 970–980 nm are inserted between collimating and focusing aspherical lenses.

Finally, to ensure the integration in structure is as compact as possible and simultaneously assure good beam pointing stability, a pointing offset insensitive compressor design has been done based on total internal reflection in PP. The compressor consists of three PPs and a transmission grating pair with 1600 lines/mm. Figure 2 shows the optical layout of the compressor. The compression chamber dimension is approximately 650 mm×250 mm×90 mm (L×W×H). Different from the highly reflective mirror (HR), the design of the pulse compressor is based on total internal reflection in PPs. On the one hand, such a design simplifies the alignment between the incident beam and output beam; on the other hand, it is also insensitive to the offset of incident beam to some extent and potentially improves the output beam pointing stability. In addition, the high line density (1600 lines/mm) and the folded optical route design between PPs realize compactness of the compressor.

Figure 2 Optical layout of PP-based transmission grating-pair compressor. G1 and G2, gratings; PP1, PP2, and PP3, Porro prisms.

3 Results and discussion

According to the principle of CPA, the seed pulses need to be stretched in temporal domain before amplification. For the studied laser system, the stretcher consists of a PM circulator, a CFBG, and a home-made temperature-controlled module used for dispersion tuning of CFBG. The utilized CFBG has group delay dispersion of 100 ps/nm and is centered at 1030 nm, and at the same time it also provides reflectivity of more than 70% and 3 dB reflection bandwidths of 12 nm. Figure 3 shows the spectra of the incident seed and stretched pulses in blue and red curves, respectively. After stretching, the spectral bandwidths and power of the pulses vary from 13.7 to 11.4 nm and from 5 to 1.87 mW, respectively.

Figure 3 Spectra of the incident seed and stretched pulses with 0.1 nm resolution. The blue curve shows the spectrum of mode-locked seed pulses and the red curve corresponds to the spectrum of stretched pulses.

Next, before reducing the repetition rates to 500 kHz, in the first pre-amplification stage, the stretched seed pulses are step-by-step amplified from 1.87 to 24.7 mW in the core-pumped 6 μm/125 μm fiber preamplifier and amplified from 24.7 to 530 mW in the 10 μm/125 μm cladding-pumped power amplifier, which respectively corresponds to 120 mW and 1.8 W pump power. The pulse duration is nearly 1 ns and the initial peak power of pulses is quite low, which facilitates realization of high-temporal-quality femtosecond pulses. The spectra after AOM have 1032.5 nm central wavelength and 9 nm spectral bandwidths. The spectrum is shown as a blue curve in Figure 4. After the AOM, the average power of 500 kHz pulse source is 4.4 mW. Subsequently, in the second pre-amplification stage, the amplified 500 kHz seed pulses with 81 mW average power in the 0.6-m-long DC gain fiber preamplifier are further launched into the 35 μm/250 μm LMA DC gain fiber amplification stage, and the average power is boosted to 10 W level under the pump power of 22 W. The pulse duration is nearly 800 ps and the estimated peak power of pulses is 25 kW. Figure 4 shows output spectrum of the 35 μm/250 μm LMA DC gain fiber amplification stage as a red curve.

Figure 4 Seed spectrum after reducing the repetition rates to 500 kHz (blue line) and output spectrum of the 35 μm/250 μm LMA DC gain fiber amplification stage (red line).

In the main amplification stage, the laser delivered from the 35 μm/250 μm gain fiber amplification stage is first collimated using a spherical lens with 30 mm focal length, and then a spherical lens with 60 mm focal length is used for coupling the laser into the rod-type PCF to be amplified. To protect the front amplifiers from being disturbed and even damaged through backward propagated laser, high-power polarization-dependent isolators are used between the adjacent gain fiber amplification stages. With reverse pumping as shown in Figure 1, under a pump power of 235 W, the maximum average output power of 97 W can be achieved. The pulse duration is nearly 600 ps and the peak power of pulses is estimated to be 0.3 MW. After the high-power isolator, the degree of polarization of amplified pulses is more than 15 dB. Figure 5 shows almost linearly increased output power versus pump power at 500 kHz repetition rates. The utilized pump source has 976.2 nm central wavelength and 0.6 nm spectral bandwidths.

Figure 5 Variation tendency of the amplified average power with the increase of pump power in the photonic crystal rod-based main amplification stage.

After the main amplifier, the amplified pulses are launched directly into the PP-based pulse compressor in double-pass configuration. As shown in Figure 2, the PP1 and PP2 are inserted between G1 and G2. The incident laser diffracts efficiently via G1 and then propagates between PP1 and PP2 via total internal reflection inside of them. Herein, the combination of PP1 and PP2 is employed to fold the optical route so as to realize compact integration. The third prism PP3 is utilized to reflect the laser beam back to the compressor for the next pass through the transmission grating pair. Compared with the conventional combination of reflective mirrors, the combination of PPs has higher structural stability as the propagation direction of output pulses is parallel to that of incident laser pulses all the time due to inherent operation characteristics of PPs. Therefore, such a design of a PP-based folded optical route not only realizes the system integration, but also potentially improves the beam pointing stability of the laser system. For comparison, we calculate the pointing drift for the PP-based compressor architecture and reflective mirror-based compressor scheme, assuming the incident angle remains constant. As shown in Figure 2, the intersecting lines between PP1 and PP2 are perpendicular to each other. As a result, the emergence angle of the output laser beam is insensitive to deviation of both pitching direction of PP2 and deflection direction of PP1, which improves the beam pointing stability. Specifically, if assuming PP2 rotates 0.1° around the x-axis, the output laser beam on incident grating G1 deviates 0.001° relative to the initial angle, and the corresponding maximum offset for the centroid position of the beam spot is less than 1 mm. However, for the reflective mirror-based compressor scheme, as the reflective mirror varies 0.1°, the corresponding centroid position offset for beam spot is at least 10 mm. Therefore, compared with conventional reflective mirror-based compressor architecture, the PP-based compressor scheme can significantly improve beam pointing stability.

After the compressor, an average power of 51 W and pulse duration as short as 830 fs are obtainable at 500 kHz repetition rates, which corresponds to more than 100 μJ single-pulse energy. It should be noted that in this laser system, the adopted pump power is actually 150 W. Higher compressible average power output is also obtainable. However, the accumulated nonlinear phase in the main amplifier significantly degrades the pulse fidelity and, thus, limits the compressibility of the amplified pulses. The spectrum of compressed amplified pulses at 51 W of average power is shown in Figure 6(a). The central wavelength and spectral bandwidths are approximately 1035 and 7 nm, respectively. In comparison with pulse spectra after the 35 μm/250 μm gain fiber amplification stage, the spectral bandwidths after the main amplifier are slightly narrowed owing to the wavelength-dependent gain and gain narrowing effects. In addition, owing to superior heat dissipation and inherent waveguide propagation characteristics, the amplified laser displays excellent beam profile recorded to exhibit a circularity of 95% and shown in Figure 6(c). As shown in Figure 6(d), the output beam also shows good beam quality with quality factor 1.3 in the horizontal direction and 1.1 in the perpendicular direction. The beam quality is very beneficial for the micro-hole manufacturing of fragile and difficult-to-machine materials.

Figure 6 Measured results at 51 W of compressed average power: (a) optical spectrum; (b) autocorrelation traces; (c) beam profile; (d) M 2 factors.

Further, power fluctuations of the compressed laser pulses have also been measured at 51 W of average power with the results shown in Figure 7(a). As can be seen, the output power exhibits excellent passive stability of 0.55% RMS in 8 h. Under the same environmental conditions, we also measure the output beam pointing stability of the presented fiber laser system at 51 W of average power. With the use of a 500 mm focal length lens and a beam analyzer, by recording the deviation of centroid position of the focal spot, the measured beam pointing stability is respectively 6 μrad/°C in the x direction and 19 μrad/°C in the y direction, which is enough for high-precision laser manufacturing. Figure 7(b) shows the measured results of pointing stability in 8 h. Both power fluctuations and beam pointing stability are simultaneously recorded as the temperature varies in a roundtrip period between 22.8°C and 26.3°C. In our work, water-cooling and the PP-based pointing offset insensitive compressor design are the main methods to assure good beam pointing stability.

Figure 7 (a) Output power fluctuations and (b) beam pointing stability of the presented laser system in 8 h at 51 W of average power and around 100 μJ single pulse energy.

4 Conclusion

In conclusion, we have developed a high-performance femtosecond fiber laser system with compact architecture based on the CPA technique of a photonic crystal rod. The combination of rod-type photonic crystal fiber and PP-based compressor design results in near-diffraction-limited beam quality and high beam pointing stability, while simultaneously preserving the key advantages of fiber laser in terms of compactness, stability, and environmental interference immunity, which are of great concern for high-quality laser precision manufacturing. As a result, we have realized up to 51 W of average power, and 830 fs pulse duration at 500 kHz repetition rates, which corresponds to around 100 μJ pulse energy, simultaneously with power fluctuations of 0.55% RMS in 8 h, pointing stability better than 20 μrad/°C in 8 h, and beam quality of M 2<1.3. The obtainable results provide a powerful base for high-quality applications of femtosecond fiber lasers in precision manufacturing fields.

Acknowledgments

This work was supported by the Key-Area Research and Development Program of Guangdong Province (No. 2018B090904003), National Natural Science Foundation of China (NSFC) (Nos. 61805274 and 6169022), and National Key R&D Program of China (No. 2018YFB1108000).

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Figure 0

Figure 1 Schematic of the photonic crystal rod-based femtosecond fiber CPA laser system. WDM, wavelength division multiplexer; PD-ISO, polarization-dependent optical isolator; AOM, acousto-optic modulator; CFBG, chirped fiber Bragg grating; HWP, half-wave plate; HR, highly reflective mirror; L1, L2, L3, lens with 30 mm, 60 mm, and 20 mm focal length, respectively.

Figure 1

Figure 2 Optical layout of PP-based transmission grating-pair compressor. G1 and G2, gratings; PP1, PP2, and PP3, Porro prisms.

Figure 2

Figure 3 Spectra of the incident seed and stretched pulses with 0.1 nm resolution. The blue curve shows the spectrum of mode-locked seed pulses and the red curve corresponds to the spectrum of stretched pulses.

Figure 3

Figure 4 Seed spectrum after reducing the repetition rates to 500 kHz (blue line) and output spectrum of the 35 μm/250 μm LMA DC gain fiber amplification stage (red line).

Figure 4

Figure 5 Variation tendency of the amplified average power with the increase of pump power in the photonic crystal rod-based main amplification stage.

Figure 5

Figure 6 Measured results at 51 W of compressed average power: (a) optical spectrum; (b) autocorrelation traces; (c) beam profile; (d) M2 factors.

Figure 6

Figure 7 (a) Output power fluctuations and (b) beam pointing stability of the presented laser system in 8 h at 51 W of average power and around 100 μJ single pulse energy.