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超短脉冲光纤激光器具有稳定性好、结构紧凑、单脉冲能量高等优点, 近年来工作在1.8—2.1 μm光谱范围内的超短脉冲激光受到了广泛的关注, 其在激光光谱学、生物医学、光通信和传感等领域具有广泛应用[1-7]. 产生脉冲的方法主要有两种: 主动调制和被动调制. 主动调制需要通过外部调制器(声光/电光调制器)来实现, 但这不仅增加了成本, 还降低了系统的便携性; 被动调制只需要在腔内加入一个振幅自调制器件, 不需要任何外部器件. 目前报道的被动调Q和锁模光纤激光器主要是基于非线性偏振演化(nonlinear polarization evolution, NPE)[8-10]以及可饱和吸收体(saturable absorber, SA)实现. 然而, 基于NPE技术的调Q和锁模激光器对腔内偏振变化敏感, 难以应用于成熟的激光产品. 利用SA进行被动调Q和锁模操作被认为是获得脉冲激光的一种方便和低成本的方法. 一个好的SA应该具有较大的调制深度、较高的损伤阈值、超快的恢复时间和宽带可饱和吸收性.
适用于1.9 μm光谱区域被动调Q和锁模激光器的SA有多种类型, 如半导体饱和吸收镜(semiconductor saturable absorber mirror, SESAM)[11]、石墨烯[12]、碳纳米管[13,14]、黑磷[15]、过渡金属硫化物[16]等. 虽然SESAM的制作工艺已经成熟, 但是其狭窄的工作带宽和昂贵的成本限制了自身的应用. 而石墨烯、碳纳米管、黑磷、过渡金属硫化物等二维材料具有损伤阈值较低的缺点. 最近, 有相关研究报道将纯水作为SA具有损伤阈值高、价格低廉、散热性能好、稳定性高的优点. 2019年, Xian等[17]利用纯水SA实现了被动调Q掺铒光纤激光器. 据我们所知, 目前还没有利用纯水SA实现被动锁模操作的报道, 实际上水分子对于1.80—1.95 μm波段的光具有很强的吸收能力[18,19], 所以本文尝试在这个波段内利用纯水SA实现锁模操作.
本文实现了一种基于纯水SA的掺铥全光纤脉冲激光器. 通过陶瓷套管将纯水固定在两个螺纹型/物理接触(ferrule contactor/physical contact, FC/PC)光纤跳线头之间, 调整水层厚度可以分别实现调Q和锁模操作. 利用纯水作为SA的材料极大地降低了激光器成本, 且由于水分子的结构非常稳定, 所以纯水SA的稳定性和损伤阈值较高. 本文为掺铥全光纤脉冲激光器提供了一种新方案.
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每个水分子具有两个氢氧键, 其能量吸收过程与氢氧键的伸缩振动和弯曲振动有关. 近红外光谱中有5个显著的水的吸收波段, 分别出现在0.76, 0.97, 1.19, 1.45和1.94 μm[18]. 1.45 μm附近的吸收带与氢氧键的伸缩振动有关, 1.94 μm附近的吸收带与氢氧键的弯曲振动有关[17,20,21]. 2.0 μm附近水的吸收光谱如图1所示. 水的频率相关振动能量弛豫时间为1ps [20,21], 远短于增益介质的上能级寿命, 因此纯水可以作为快速SA来实现锁模操作.
图 1 纯水的吸收光谱
Figure 1. Absorption spectrum of pure water.
实验结构如图2所示, 该环形腔包含1.5 m长的掺铥光纤, 其型号为Nufern SM-TSF-9/125, 由1550 nm连续光激光器通过1550/2000 nm波分复用器进行泵浦. 采用偏振无关隔离器保证激光器的单向工作. 通过插入偏振控制器来调节激光在腔内的偏振状态, 以获得最佳工作状态. 将纯水SA通过陶瓷套管固定在两个FC/PC光纤跳线头之间, 实验中用到的陶瓷套管取自FC/PC光纤连接器, 纯水为纯度99.99%的去离子水. 首先取出一盆纯水, 将陶瓷套管完全浸没在纯水中并去除套管内的空气. 然后将一对光纤跳线头用纯水擦拭后分别插入陶瓷套管的两端, 跳线头之间的间隙充满纯水, 该步骤全程在纯水中操作, 以防止间隙中出现气泡. 轻轻推动跳线头便可以改变间隙的大小从而调节水层的厚度, 因此很容易获得不同调制深度的SA, 这是液体SA的独特优势. 用90∶10的光耦合器从激光腔中耦合出10%的腔内能量作为输出. 环形腔的总长度约为11.31 m, 腔内无源光纤的型号均为Nufern SM-1950, 环形腔总色散处于负色散区域. 利用光谱分析仪(ANDO AQ6317B)和2 GHz射频频谱分析仪(AV4021)分别测量激光器的光谱和射频频谱特性, 时域特性则由4 GHz示波器(Teledyne LeCroy WaveRunner 640Zi)和自相关仪(APE PulseCheck SM250)记录.
图 2 纯水SA掺铥光纤激光器的实验结构 TDF, 掺铥光纤; WDM, 波分复用器; PI-ISO, 偏振无关隔离器; PC, 偏振控制器; OC, 光耦合器; SA, 可饱和吸收体
Figure 2. Experimental setup of pure water-SA Tm-doped fiber laser: TDF, Tm-doped fiber; WDM, wavelength division multiplexer; PI-ISO, polarization independent isolator; PC, polarization controller; OC, optical coupler; SA, saturable absorber.
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当泵浦功率提高到152 mW时, 通过改变水层厚度和调节PC可以获得被动调Q脉冲输出, 图3(a)—(c)分别是泵浦功率为152, 238, 311 mW时的调Q脉冲序列, 显微镜下测量得到此时的水层厚度大约为0.2 mm. 当泵浦功率增加时, 脉冲的重复频率变高, 这是调Q脉冲的典型特征. 图4给出了泵浦功率为152 mW时的调Q光谱, 其中心波长为1870.04 nm, 3 dB光谱带宽为6.57 nm. 光谱上大量的凹陷源于水的强烈吸收[22]. 脉冲输出功率和单脉冲能量随泵浦功率的变化如图5(a)所示, 脉冲宽度和重复频率随泵浦功率的变化如图5(b)所示. 当泵浦功率从152 mW增加到311 mW时, 输出功率从0.135 mW增加到0.531 mW, 单脉冲能量从6.33 nJ增加到9.94 nJ, 脉冲宽度从6.92 μs减小到3.01 μs, 重复频率从21.31 kHz增加到53.45 kHz. 与锁模操作不同, 调Q脉冲的重复频率取决于泵浦功率而不是腔长. 当泵浦功率增大时, 为SA提供了更高的增益, SA的饱和速度更快, 这导致了重复频率的增加.
图 3 泵浦功率不同时的调Q脉冲序列 (a) 152 mW; (b) 238 mW; (c) 311 mW
Figure 3. Q-switched pulse trains under different pump powers: (a) 152 mW; (b) 238 mW; (c) 311 mW.
图 4 泵浦功率为152 mW时的调Q光谱
Figure 4. Q-switched optical spectrum under pump power of 152 mW.
图 5 (a) 输出功率和单脉冲能量随泵浦功率的变化; (b) 脉冲宽度和重复频率随泵浦功率的变化
Figure 5. (a) Output power and single-pulse energy as a function of pump power; (b) pulse width and repetition rate as a function of pump power.
当泵浦功率为311 mW, 水层厚度约为0.1 mm时, 仔细调节PC可以得到稳定的锁模脉冲输出, 此时的输出功率为2.28 mW, 已经达到泵浦激光器最大功率, 无法继续提升泵浦功率. 示波器测得的脉冲序列如图6(a)所示, 脉冲间隔为56.53 ns, 与激光器的腔长相吻合. 图6(b)展示了脉冲的自相关轨迹, 测得脉冲宽度为1.42 ps. 如图6(c)所示, 此时测得输出激光的中心波长为1884.68 nm, 3 dB光谱宽度为4.27 nm, 计算得到时间带宽积为0.512, 略大于傅里叶变换极限双曲正割脉冲的理论值0.315, 说明脉冲存在啁啾. 此外可以看到光谱有很明显的Kelly边带, 说明激光器输出为典型的孤子脉冲. 锁模光谱上大量的凹陷和调Q光谱类似, 也是源于水的强烈吸收[22]. 由图1的纯水吸收谱可知, 在1850—1940 nm波长内, 纯水SA对不同波长的损耗不同, 存在滤波效果. 当激光器处于锁模状态时, 水层的厚度比调Q状态下小, 此时纯水SA整体插损降低, 滤波效果下降, 因此谐振中心波长发生变化. 此外, 锁模状态下脉冲的峰值功率更高, 非线性效应会产生更多的频率成分, 这也会对激光器的输出中心波长产生影响. 图6(d)为输出激光的射频频谱, 重复频率为17.69 MHz, 68 dB的信噪比说明锁模状态非常稳定. 此外, 我们测量了锁模脉冲的长时间稳定性, 如图7所示. 在两个小时内, 输出锁模脉冲序列几乎保持不变, 锁模状态表现出较高的稳定性.
图 6 (a) 示波器测得的锁模脉冲序列; (b) 输出锁模脉冲的自相关轨迹; (c) 锁模状态的输出光谱; (d) 锁模状态的输出射频频谱
Figure 6. (a) Mode-locked pulse train measured by oscilloscope; (b) autocorrelation trace of the output mode-locked pulse; (c) output optical spectrum of the mode-locked state; (d) output radio frequency spectrum of the mode-locked state.
图 7 锁模脉冲的长时间稳定性
Figure 7. The long-time stability of mode-locked pulses.
为了表征纯水SA的非线性响应, 我们用1.9 μm波段锁模光纤激光器作为探测光源进行测量, 探测光脉冲宽度为2.9 ps, 重复频率为33.07 MHz. 10%的输出功率用于监测输入功率, 而90%的剩余激光则进入纯水SA. 通过改变入射功率得到了纯水SA透过率的变化如图8所示典型的饱和吸收曲线, 可以用饱和模型方程来描述:
图 8 纯水SA在1.9 μm波长下的非线性响应
Figure 8. Nonlinear response of the pure water SA at 1.9 μm wavelength.
$ T\left( I \right) = 1 - \Delta T\exp \left( { - \frac{I}{{{I_{{\text{sat}}}}}}} \right) - {T_{{\text{ns}}}} \text{, } $ 其中
$ T\left( I \right) $ 为透过率,$ \Delta T $ 为调制深度, I为输入脉冲峰值强度,$ {I_{{\text{sat}}}} $ 为饱和强度,$ {T_{{\text{ns}}}} $ 为非饱和损耗. 通过计算得到, 纯水SA的调制深度约为4.8%, 非饱和损耗约为45.6%, 饱和强度约为0.12 GW/cm2.实验中, 通过改变纯水SA的厚度分别得到了调Q和锁模脉冲, 虽然都是利用纯水SA的可饱和吸收效应实现的, 但是二者的原理不同. 当纯水SA的厚度较大且泵浦功率较低时, 腔内的损耗较高且增益较低, 反转粒子数更容易积累, 因此容易产生调Q脉冲. 当纯水SA的厚度较小并且泵浦功率较高时, 腔内容易激发出更多的纵模, 因此有利于锁模脉冲的产生.
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本文搭建了基于纯水SA的掺铥全光纤脉冲激光器, 调节SA厚度分别实现了调Q和锁模操作. 稳定的调Q脉冲最大输出功率为0.531 mW, 此时的重复频率为53.45 kHz, 脉冲宽度为3.01 μs. 而锁模状态下输出功率提升至2.28 mW, 这是由于水层厚度的降低减小了插损, 锁模脉冲的重复频率为17.69 MHz, 脉冲宽度为1.42 ps. 使用纯水作为SA的被动锁模光纤激光器, 考虑到其皮秒级的响应时间、低廉的价格和极高的损伤阈值, 基于纯水的SA可能在超快光纤激光器领域有着更广泛的运用.
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All-fiber laser with short pulses possesses many advantages, such as superior stability, compact structure, and high single pulse energy. Recently, short pulse laser working in a 1.8–2.0 μm spectral region has received considerable attention due to its wide applications in laser spectroscopy, biomedicine, optical communications and sensing. The passive Q-switched and mode-locked operations by saturable absorber (SA) have been considered to be convenient and low-cost ways to achieve short pulses. Recently, pure water has been reported as the ideal SA because of its advantages of high damage threshold, low prices, good thermal diffusivity and stability. In this work, Tm-doped all-fiber pulse laser based on pure water as the SA is demonstrated. The pure water is fixed between two FC/PC fiber patchcord by the ceramic cannula, so we can change the loss of SA easily. The Q-switched and mode-locked operations can be obtained by adjusting the water layer thickness. The maximum output power at Q-switched state is 0.531 mW, the repetition frequency is 53.45 kHz, and the pulse width is 3.01 μs. The maximum output power at mode-locked state is 2.28 mW, the repetition rate is 17.69 MHz, and the pulse width is 1.42 ps. To our knowledge, this is the first passive mode-locked fiber laser using pure water as a saturable absorber, and provides a new scheme for thulium-doped all-fiber pulse lasers.
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Keywords:
- Tm-doped fiber laser /
- saturable absorber /
- Q-switched /
- mode-locked
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图 2 纯水SA掺铥光纤激光器的实验结构 TDF, 掺铥光纤; WDM, 波分复用器; PI-ISO, 偏振无关隔离器; PC, 偏振控制器; OC, 光耦合器; SA, 可饱和吸收体
Fig. 2. Experimental setup of pure water-SA Tm-doped fiber laser: TDF, Tm-doped fiber; WDM, wavelength division multiplexer; PI-ISO, polarization independent isolator; PC, polarization controller; OC, optical coupler; SA, saturable absorber.
图 3 泵浦功率不同时的调Q脉冲序列 (a) 152 mW; (b) 238 mW; (c) 311 mW
Fig. 3. Q-switched pulse trains under different pump powers: (a) 152 mW; (b) 238 mW; (c) 311 mW.
图 5 (a) 输出功率和单脉冲能量随泵浦功率的变化; (b) 脉冲宽度和重复频率随泵浦功率的变化
Fig. 5. (a) Output power and single-pulse energy as a function of pump power; (b) pulse width and repetition rate as a function of pump power.
图 6 (a) 示波器测得的锁模脉冲序列; (b) 输出锁模脉冲的自相关轨迹; (c) 锁模状态的输出光谱; (d) 锁模状态的输出射频频谱
Fig. 6. (a) Mode-locked pulse train measured by oscilloscope; (b) autocorrelation trace of the output mode-locked pulse; (c) output optical spectrum of the mode-locked state; (d) output radio frequency spectrum of the mode-locked state.
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[1] Barnes N P, Walsh B M, Reichle D J, Deyoung R J 2009 Opt. Mater. 31 1061
Google Scholar
[2] Zipfel W R, Williams R M, Webb W W 2003 Nat. Biotechnol. 21 1369
Google Scholar
[3] Steinlechner J, Martin I W, Bell A S, Hough J, Fletcher M, Murray P G, Robie R, Rowan S, Schnabel R 2018 Phys. Rev. Lett. 120 263602
Google Scholar
[4] Tan S, Yang L, Wei X, Li C, Chen N, Tsia K K, Wong K K 2017 Opt. Lett. 42 1540
Google Scholar
[5] Zhang H, Kavanagh N, Li Z, et al. 2015 Opt. Express 23 4946
Google Scholar
[6] Fried N M 2005 Lasers Surg. Med. 36 52
Google Scholar
[7] Hu J, Menyuk C R, Shaw L B, Sanghera J S, Aggarwal I D 2010 Opt. Lett. 35 2907
Google Scholar
[8] Fermann M E, Andrejco M J, Silberberg Y, Stock M L 1993 Opt. Lett. 18 894
Google Scholar
[9] Yan Z Y, Li X H, Tang Y L, Shum P P, Yu X, Zhang Y, Wang Q J 2015 Opt. Express 23 4369
Google Scholar
[10] Sun B, Luo J Q, Ng B P, Yu X 2016 Opt. Lett. 41 4052
Google Scholar
[11] Lagatsky A A, Fusari F, Calvez S, Gupta J A, Kisel V E, Kuleshov N V, Brown C T A, Dawson D, Sibbett W 2009 Opt. Lett. 34 2587
Google Scholar
[12] Peng Y, Wei X, Wang W 2012 Laser Phys. Lett. 9 15
Google Scholar
[13] Liu J, Wang Y, Qu Z, Fan X 2012 Opt. Laser Technol. 44 960
Google Scholar
[14] Wang Y, Alam S U, Obraztsova E D, Pozharov A S, Set S Y, Yamashita S 2016 Opt. Lett. 41 3864
Google Scholar
[15] Kong L, Qin Z, Xie G, Guo Z, Zhang H, Yuan P, Qian L 2016 Laser Phys. Lett. 13 045801
Google Scholar
[16] Jung M, Lee J, Park J, Koo J, Jhon Y M, Lee J H 2015 Opt. Express 23 19996
Google Scholar
[17] Xian T, Zhan L, Gao L, Zhang W, Zhang W 2019 Opt. Lett. 44 863
Google Scholar
[18] Curcio J A, Petty C C 1951 J. Opt. Soc. Am. 41 302
Google Scholar
[19] Zou W, Xu X, Xu R, Fan X, Zhao Y, Li L, Tang D, Shen D 2017 Photonics Res. 5 583
Google Scholar
[20] Deàk J C, Rhea S T, Iwaki L K, Dlott D D 2000 J. Phys. Chem. A 104 4866
Google Scholar
[21] Woutersen S, Bakker H J 1999 Nature 402 507
Google Scholar
[22] Li G, Zhou Y, Li S, Yao P, Gao W, Gu C, Xu L 2018 Chin. Phys. Lett. 35 114203
Google Scholar
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