LI Bei, YU Haijuan, HE Chaojian, QI Yaoyao, CHEN Han, LIN Xuechun
(Laboratory of All-solid-state Light Sources, Institute of Semiconductors, Chinese Academy of Sciences, Beijing 100083, China; College of Materials Science and Opto-Electronic Technology, University of Chinese Academy of Sciences, Beijing 101407, China; Beijing Engineering Technology Research Center of All-solid-state Lasers Advanced Manufacturing, Beijing 100083, China) (Received 7 April 2017; Revised 22 May 2017)
Abstract We demonstrated an intracavity frequency-doubled passively mode-locked Nd∶LuVO4-LBO green laser with SESAM as the saturable absorber. The maximum average output power was 385 mW when the pump power was 9.3 W. The pulse width was 17.6 ps and the repetition rate was 76 MHz. The optical conversion efficiency from the pumping diode laser to the green laser was 4.1%. We observed the interference of the frequency-doubled green light with the normal operation of SESAM, analyzed the reason, and eventually resolved the problem.
Keywords intracavity frequency-doubled; Nd∶LuVO4; mode-locked green laser
Ultrashort picosecond pulses are widely used in many areas, such as medicine, material processing, and scientific research[1-2]. In particular, the ultrafast picosecond green lasers with high repetition rate have been substantially investigated[3]. Such pulses can be generated by frequency doubling of mode-locked picosecond lasers. Recently,a great deal of efforts have concentrated on the Q-switched mode-locked or continuous-wave (CW) mode-locked intracavity frequency-doubled green laser with saturable absorber[4-7]. Pang et al.[8-9]reported a semiconductor saturable absorber mirror (SESAM) passive mode-locked Nd∶YVO4intracavity frequency-doubled laser with a potassium titanyl phosphate crystal (KTP) and a lithium triborate crystal (LBO). They obtained 90 mW picosecond green output with a pulse duration of 29.7 ps by KTP and 140 mW with 3.67 ps by LBO. Later, Cai et al.[10]investigated a passively CW mode-locked green laser using Nd∶YVO4with KTP. They selected reflective single-walled carbon nanotubes to achieve mode-locking and produced 456 mW output power with a pulse width of 7.1 ps. Recently, Li et al.[11]demonstrated a CW Kerr-lens mode-locked Nd∶YVO4laser and frequency doubled with KTP. The repetition rate was 1.1 GHz and the output power of the green laser was 258 mW. Due to the weak thermal conduction of Nd∶YVO4crystal, researchers[12]demonstrated a passively mode-locked laser using a YVO4/Nd∶YVO4composite crystal with KTP as the frequency-doubling crystal and obtained a maximum output power of 2.06 W of the green laser with a pulse width of 18 ps. Li et al.[13]reported a SESAM mode-locked Nd∶GdVO4laser (frequency doubled with KTP) and they achieved 396 mW output at 532 nm and a pulse duration of 5.5 ps. As seen in the above-mentional references, research interests have focused on Nd∶GdVO4and Nd∶YVO4lasers with KTP and LBO as the nonlinear media for frequency doubling. It is well-known that Nd∶LuVO4is a vanadate crystal with many excellent properties[14]. Its emission and absorption cross sections are 14.6×10-19cm2at 1 064 nm and 6.9×10-19cm2at 808 nm, respectively, which are higher than those of Nd∶YVO4and Nd∶GdVO4[15-16]. In addition, its thermal conductivity is better than that of Nd∶YVO4. Therefore, a mode-locked Nd∶LuVO4laser is also a suitable candidate for intracavity frequency doubling.
In this manuscript, we describe an intracavity frequency-doubled green laser at 532 nm using a SESAM mode-locked Nd∶LuVO4laser at 1 064 nm with LBO. Experimentally, we chose the LBO crystal for second-harmonic generation due to its large angular and temperature acceptances and high damage threshold[17]. The maximum output power was 385 mW when the pump power was 9.3 W. The corresponding repetition rate was 76 MHz and the pulse width was 17.6 ps.
The experimental apparatus was shown in Fig.1. A simple folding cavity was used. The pumping laser was a fiber-coupled diode laser (DILAS:M1F1S22-808.3-35C-T25-SS2. 13-2 m SMA). It was cooled at a temperature of 18 ℃ with circulating water and its emission wavelength was 808 nm. The pigtailed fiber had a numerical aperture (NA) of 0.22 and a core diameter of 105 μm. The pump light was coupled with a beam expanding system (expansion ratio 1∶3) and focused on the Nd∶LuVO4crystal. The laser crystal was planar cut with its optical axis parallel to the propagation direction. Its dimensions were 3 mm×3 mm×6 mm with 0.5 at.% doping of Nd. A water-cooled copper holder was selected for cooling the crystal, which was wrapped with indium foil. The pump side of the laser crystal was antireflection (AR) coated both at 1 064 nm and 808 nm while the other side was AR coated at 1 064 nm to reduce Fresnel loss in the cavity. The LBO crystal, whose dimensions were 3 mm×3 mm×20 mm,was cut for type-I phase matching withθ=90°,φ=0°. Its operation temperature was set atT=152 ℃. Both ends of the LBO were AR coated at 532 nm and 1 064 nm to reduce loss. The SESAM soldered on a small copper block was a commercial product of BATOP. Its central wavelength was at 1 064 nm and the saturation fluence was 90 μJ/cm2.
Fig.1 Experimental setup of intracavity frequency-doubled passive mode-locked Nd∶LuVO4-LBO green laser
The input mirror M1 was high reflection (HR) coated at 1 064 nm and AR coated at 808 nm. The flat mirror M2 was HR coated at 1 064 nm. The concave mirror M3 with curvature radius of 1 000 mm was HR coated at 1 064 nm. M4 was AR coated at 532 nm and HR at 1 064 nm, to allow the transmittance of the green laser. The focusing lens M5, with a focal length of 150 mm, was AR coated both at 1 064 nm and 532 nm. M6 was AR coated at 1 064 nm and HR at 532 nm. The total length of the cavity was approximately 1.95 m.
First, to observe the laser operation, we replaced M2 with an output coupler (OC) with 3% transmission and tried to obtain mode locking at the fundamental wavelength. We successfully realized a CW passive mode-locked laser when the pump power was 2.79 W or higher. As the pump power increased, the output power increased linearly. The maximum output power reached 1.6 W when the pump power was 9.3 W. The optical-to-optical conversion efficiency from the pump to the output at 1 064 nm was 17.2%.
Then, we inserted the LBO in the cavity, and carefully adjusted the alignment. Finally, we replaced 3% OC with the M2. Heating the LBO crystal to achieve noncritical phase matching, and eventually we obtained the frequency doubled green laser. The average output power of the green laser as a function of the pump power was shown in Fig. 2. When the pump power reached 9.3 W, the maximum output power of the frequency-doubled green laser was 385 mW and the optical conversion efficiency was 4.1% from the pump light to the green laser.
Fig.2 Output power of green laser versus pump power
In our experiment, we found that the threshold for achieving the continuous wave mode-locked green laser occurred at a pump power of 4.19 W. Obviously, inserting the LBO into the cavity increased the threshold of the mode locking. The main reasons were as follows. First, the spot size on the SESAM became larger after inserting the LBO and, as a result, the laser energy density on the SESAM was reduced. Second, introducing the LBO into the cavity increased the cavity loss due to the residual Fresnel losses on the crystal’s surfaces, while the process of frequency doubling would consume part of the fundamental beam and thus increased the loss in the laser cavity.
The autocorrelation trace of the mode locked Nd∶LuVO4laser pulses measured by an autocorrelator (SM-1200, APE Inc.) was shown in Fig. 4. It was found that the pulse duration was 24.9 ps for the fundamental output by assuming a sech2pulse shape. So the pulse width of the green laser was calculated to be approximately 17.6 ps.
Figure 5 gave the spectrum of the picosecond green laser, as detected by a spectrometer (AvaSpec-ULS3648-4-USB2 with a resolution of 0.14 nm). Its full width at half maximum (FWHM)was 0.27 nm before deconvolution.
Fig.3 Pulse trains of the green laser in time scales of 100 ns/div (a) and 10 ns/div (b), respectively
Fig.4 Autocorrelation trace (hollow diamond) of mode-locked Nd∶LuVO4 laser pulses and sech2 fitting (filled circle)
Fig.5 Spectrum of the picosecond green laser
Fig.6 Beam quality parameter M2 measurement for the mode-locked green laser (the upper inset: 2D near-field energy fluence profile)
At the beginning, M6, which was HR coated at 532 nm and AR coated at 1 064 nm, was not used in the resonator when the laser was operated in mode-locking at 1 064 nm. However, it was interesting to note that when we adjusted the temperature of the LBO to optimize the output power of the green laser, we found that the generated green laser was a continuous wave and no mode-locking was seen. At this point, we replaced M2 with the 3% OC and found that the fundamental frequency light was also a continuous wave. When the LBO temperature dropped to room temperature and no frequency-doubling was generated, the mode locking of the fundamental laser immediately resumed. Apparently, it was the generated green laser that interrupted the mode locking. To maintain stable mode-locking, one needs to block the interference of the green light. A dichroic mirror M6, which allowed the laser to pass through at 1 064 nm and be blocked at 532 nm, was introduced to the resonator to prevent the green light from shining on the SESAM and to maintain both mode locking of fundamental laser and generation of the green laser.
It is clear that the process of saturable absorption is affected by the generated green laser. As we all know that semiconductor absorbers have an intrinsic bitemporal impulse response. The slower response, interband trapping and recombination processes, plays a vitally important part in starting the pulse formation process and for pulse forming in picosecond pulsed lasers[19-20]. The process of saturable absorption can be summarized as follows: at high optical intensities, the initial states are depleted so that the absorption is reduced and an optical pulse is formed[21]. When the green laser hits the saturable absorber, both the fundamental laser and the green laser will be more or less absorbed simultaneously. The photon energy of the green laser is greater than the band-gap energy of the saturable absorber,which has less energy than that of the fundamental frequency of the laser[22]. So we believe that the green laser generated in the CW mode destroyed the saturable absorption of the SESAM. The process of periodic loss modulation in the absorbers is disturbed and the mode locking is interrupted[21-23]. Therefore, it is necessary to insert M6 into the cavity to avoid the green light interfering with the SESAM and to maintain both the mode locking of the fundamental laser and the frequency-doubled green laser. This is a useful lesson for constructing an intracavity frequency-doubled laser using SESAM as the mode-locker.