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High-brightness broadband mid-infrared supercontinuum sources are highly demanded for many applications such as remote sensing, environmental monitoring, manufacturing industry, medical surgery and thermal imaging. For fulfilling these applications, high average power output is required. Compared with all other mid-infrared glass fibers, chalcogenide glass fiber possesses low phonon energy, long wavelength transmission edge, and high Kerr nonlinearity, thereby becoming a uniquely ideal nonlinear optical material for generating broadband mid-infrared supercontinuum. Unfortunately, due to weak chemical bonds forming the glass network, the commonly used As-S chalcogenide glass has a relatively low laser damage threshold. Thus from the material aspect, it limits high power yielded from a chalcogenide fiber based mid-infrared supercontinuum source. A chalcogenide glass host with enhanced laser damage threshold is therefore needed for further power scaling up of such a mid-infrared fiber supercontinuum. In this work, we introduce germanium into a traditional As-S glass system. The laser damage threshold of Ge-As-S glass is investigated systematically. A 3.6-μm femtosecond laser is employed as an excitation source. The relationship between the laser damage threshold and the glass composition indicates that of the studied Ge-As-S chalcogenide glasses, stoichiometric Ge0.25As0.1S0.65 glass possesses the highest laser damage threshold. In the following fiber design and fabrication, the optimized stoichiometric Ge0.25As0.1S0.65 glass therefore is chosen as a core material of the designed fiber, while a compatible Ge0.26As0.08S0.66 glass is selected as a cladding material. A step-index nonlinear fiber with a core diameter of 15 μm is fabricated by the traditional rod-in-tube method. The numerical aperture and the background loss of the fabricated Ge0.25As0.1S0.65/Ge0.26As0.08S0.66 fiber are ~0.24 and < 2 dB/m, respectively. Broadband mid-infrared supercontinuum is generated in the fiber by using an anomalous-dispersion pumping scheme. A 4.8-μm femtosecond laser with a pulse duration of 170 femtosecond and a repetition rate of 100 kHz is adopted as a pump source. The guidance of the fundamental mode is confirmed under low pump power level. With the increase of the pump power, the supercontinuum shows to be significantly broadened. Broadband supercontinuum ranging from 2.5 μm to 7.5 μm is generated in an only 10-cm-long fiber, when the maximum coupled pump power is 15 mW, equivalent to a peak power of 882 kW. The power output of the supercontinuum is 5.5 mW. All in all, the results indicate that the Ge-As-S chalcogenide glass fiber is a promising nonlinear medium for broadband mid-infrared supercontinuum sources with high brightness. [1] Petersen C R, Moller U, Kubat I, Zhou B, Dupont S, Ramsay J, Benson T, Sujecki S, Abdel-Moneim N, Tang Z, Furniss D, Seddon A, Bang O 2014 Nat. Photonics 8 830
Google Scholar
[2] Yu Y, Gai X, Ma P, Vu K, Yang Z, Wang R, Choi D Y, Madden S, Luther-Davies B 2016 Opt. Lett. 41 958
[3] Cheng T, Nagasaka K, Tuan T H, Xue X, Matsumoto M, Tezuka H, Suzuki T, Ohishi Y 2016 Opt. Lett. 41 2117
Google Scholar
[4] Shi H, Feng X, Tan F, Wang P, Wang P 2016 Opt. Mater. Express 6 3967
Google Scholar
[5] Jiang X, Joly N Y, Finger M A, Babic F, Wong G K L, Travers J C, Russell P S J 2015 Nat. Photonics 9 133
Google Scholar
[6] Zhao Z, Chen P, Wang X, Xue Z, Tian Y, Jiao K, Wang X-g, Peng X, Zhang P, Shen X, Dai S, Nie Q, Wang R 2019 J. Am. Ceram. Soc. 102 5172
Google Scholar
[7] Wei H F, Chen S P, Hou J, Chen K K, Li J Y 2016 Chin. Phys. Lett. 33 64202
Google Scholar
[8] Boivin M, El-Amraoui M, Ledemi Y, Celarie F, Vallee R, Messaddeq Y 2016 Opt. Mater. Express 6 1653
Google Scholar
[9] Rezvani S A, Nomura Y, Ogawa K, Fuji T 2019 Opt. Express 27 24499
Google Scholar
[10] Li G, Peng X, Dai S, Wang Y, Xie M, Yang L, Yang C, Wei W, Zhang P 2018 J. Lightwave Technol. 37 1847
Google Scholar
[11] Zhang B, Yu Y, Zhai C, Qi S, Wang Y, Yang A, Gai X, Wang R, Yang Z, Luther-Davies B 2016 J. Am. Ceram. Soc. 99 2565
Google Scholar
[12] Zhao Z, Wu B, Wang X, Pan Z, Liu Z, Zhang P, Shen X, Nie Q, Dai S, Wang R 2017 Laser Photonics Rev. 11 1700005
Google Scholar
[13] Dai S, Wang Y, Peng X, Zhang P, Wang X, Xu Y 2018 Appl. Sci. 8 707
Google Scholar
[14] Yao C, Jia Z, Li Z, Jia S, Zhao Z, Zhang L, Feng Y, Qin G, Ohishi Y, Qin W 2018 Optica 5 1264
Google Scholar
[15] Gattass R R, Shaw L B, Nguyen V Q, Pureza P C, Aggarwal I D, Sanghera J S 2012 Opt. Fiber Technol. 18 345
Google Scholar
[16] Robichaud L R, Duval S, Pleau L P, Fortin V, Bah S T, Chatigny S, Vallee R, Bernier M 2020 Opt. Express 28 107
Google Scholar
[17] Zhang M, Li T, Yang Y, Tao H, Zhang X, Yuan X, Yang Z 2019 Opt. Mater. Express 9 555
Google Scholar
[18] You C, Dai S, Zhang P, Xu Y, Wang Y, Xu D, Wang R 2017 Sci. Rep. 7 6497
[19] Zhu L, Yang D, Wang L, Zeng J, Zhang Q, Xie M, Zhang P, Dai S 2018 Opt. Mater. 85 220
Google Scholar
[20] Zhang Y, Xu Y, You C, Xu D, Tang J, Zhang P, Dai S 2017 Opt. Express 25 8886
Google Scholar
[21] Messaddeq S H, Vallee R, Soucy P, Bernier M, El-Amraoui M, Messaddeq Y 2012 Opt. Express 20 29882
Google Scholar
[22] 李铜铜, 张鸣杰, 田康振, 张翔, 袁孝, 杨安平, 杨志勇 2019 光学学报 39 1016001
Google Scholar
Li T T, Zhang M J, Tian K Z, Zhang X, Yuan X, Yang A P, Yang Z Y 2019 Acta Opt. Sin. 39 1016001
Google Scholar
[23] Zhang M, Li L, Li T, Wang F, Tian K, Tao H, Feng X, Yang A, Yang Z 2019 Opt. Express 27 29287
Google Scholar
[24] Sun M, Yang A, Zhang X, Ma H, Zhang M, Tian K, Feng X, Yang Z 2019 J. Am. Ceram. Soc. 102 6600
Google Scholar
[25] Zhang M, Yang Z, Zhao H, Yang A, Li L, Tao H 2017 J. Alloys Compd. 722 166
Google Scholar
[26] Lu X, Lai Z, Zhang R, Guo H, Ren J, Strizik L, Wagner T, Farrell G, Wang P 2019 J. Eur. Ceram. Soc. 39 3373
Google Scholar
[27] 乔北京, 陈飞飞, 黄益聪, 戴世勋, 聂秋华, 徐铁峰 2015 物理学报 64 154216
Google Scholar
Qiao B J, Chen F F, Huang Y C, Dai S X, Nie Q H, Xu T F 2015 Acta Phys. Sin. 64 154216
Google Scholar
[28] Liu L, Zheng X, Xiao X, Xu Y, Cui X, Cui J, Guo C, Yang J, Guo H 2019 Opt. Mater. Express 9 3582
Google Scholar
[29] 杨艳, 陈云翔, 刘永华, 芮扬, 曹烽燕, 杨安平, 祖成奎, 杨志勇 2016 物理学报 65 127801
Google Scholar
Yang Y, Chen Y X, Liu Y H, Rui Y, Cao F Y, Yang A P, Zu C K, Yang Z Y 2016 Acta Phys. Sin. 65 127801
Google Scholar
[30] Yang Y, Zhang B, Yang A, Yang Z, Lucas P 2015 J. Phys. Chem. B 119 5096
Google Scholar
[31] Zhang B, Guo W, Yu Y, Zhai C, Qi S, Yang A, Li L, Yang Z, Wang R, Tang D, Tao G, Luther-Davies B 2015 J. Am. Ceram. Soc. 98 1389
Google Scholar
[32] Snopatin G E, Shiryaev V S, Plotnichenko V G, Dianov E M, Churbanov M F 2009 Inorg. Mater. 45 1439
Google Scholar
[33] Nguyen V Q, Sanghera J S, Kung F H, Aggarwal I D, Lloyd I K 1999 Appl. Opt. 38 3206
Google Scholar
[34] Dudley J M, Genty G, Coen S 2006 Rev. Mod. Phys. 78 1135
Google Scholar
[35] Biancalana F, Skryabin D V, Yulin A V 2004 Phys. Rev. E 70 016615
Google Scholar
[36] Eftekhar M A, Wright L G, Mills M S, Kolesik M, Correa R A, Wise F W, Christodoulides D N 2017 Opt. Express 25 9078
Google Scholar
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图 1 SC测试实验装置示意图
Figure 1. Experimental setup for mid-infrared SC measurements
图 2 Ge-As-S玻璃的Ith与化学组成的关联
Figure 2. Correlation between the Ith and dS of Ge-As-S glasses.
图 3 Ge-As-S玻璃的 (a) 透过光谱(玻璃厚度为3.7 mm)和 (b) DSC曲线
Figure 3. (a) Transmission spectra and (b) DSC curves of Ge-As-S glasses.
图 4 Ge-As-S玻璃的线性折射率n0及光纤的NA
Figure 4. Measured refractive indices of Ge-As-S glasses and the calculated NA of the fiber.
图 5 Ge0.25As0.1S0.65玻璃和芯径为15μm的Ge0.25As0.1S0.65/Ge0.26As0.08S0.66光纤的色散曲线
Figure 5. Dispersion curves of Ge0.25As0.1S0.65 glass and Ge0.25As0.1S0.65/Ge0.26As0.08S0.66 fiber with a core diameter of 15 μm.
图 6 Ge0.25As0.1S0.65/Ge0.26As0.08S0.66玻璃光纤的损耗谱, 插图为光纤的横截面
Figure 6. Attenuation of fabricated Ge0.25As0.1S0.65/Ge0.26As0.08S0.66 fiber. The inset is the cross section of the fiber.
图 7 (a) Ge-As-S光纤输出光斑; (b) 采用4.8 μm激光(170 fs, 100 kHz)抽运芯径为15 μm的Ge0.25As0.1S0.65/Ge0.26As0.08S0.66玻璃光纤获得的SC输出
Figure 7. (a) Measured light spot at the output end of the Ge-As-S fiber; (b) Measured SC generated in the Ge0.25As0.1S0.65/Ge0.26As0.08S0.66 fiber with a core diameter of 15 µm when pumped at 4.8 µm (170 fs, 100 kHz).
表 1 Ge-As-S玻璃在中心波长为3.6 μm、脉冲宽度为170 fs、重复频率为100 kHz激光辐照下的Ith
Table 1. Ith of Ge-As-S glasses under the irradiation of 170 fs pulses with the repetition rates of 100 kHz at 3.6 μm.
Composition dS /at. % Ith/GW·cm–2 Ge0.1As0.1S0.8 45 462 Ge0.15As0.1S0.75 30 498 Ge0.1As0.2S0.7 20 550 Ge0.2As0.1S0.7 15 589 Ge0.15As0.2S0.65 5 609 Ge0.25As0.1S0.65 0 638 Ge0.2As0.2S0.6 –10 530 Ge0.3As0.1S0.6 –15 465 Ge0.25As0.20S0.55 –25 425 Ge0.35As0.1S0.55 –30 392 Ge0.3As0.2S0.5 –40 350 
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[1] Petersen C R, Moller U, Kubat I, Zhou B, Dupont S, Ramsay J, Benson T, Sujecki S, Abdel-Moneim N, Tang Z, Furniss D, Seddon A, Bang O 2014 Nat. Photonics 8 830
Google Scholar
[2] Yu Y, Gai X, Ma P, Vu K, Yang Z, Wang R, Choi D Y, Madden S, Luther-Davies B 2016 Opt. Lett. 41 958
[3] Cheng T, Nagasaka K, Tuan T H, Xue X, Matsumoto M, Tezuka H, Suzuki T, Ohishi Y 2016 Opt. Lett. 41 2117
Google Scholar
[4] Shi H, Feng X, Tan F, Wang P, Wang P 2016 Opt. Mater. Express 6 3967
Google Scholar
[5] Jiang X, Joly N Y, Finger M A, Babic F, Wong G K L, Travers J C, Russell P S J 2015 Nat. Photonics 9 133
Google Scholar
[6] Zhao Z, Chen P, Wang X, Xue Z, Tian Y, Jiao K, Wang X-g, Peng X, Zhang P, Shen X, Dai S, Nie Q, Wang R 2019 J. Am. Ceram. Soc. 102 5172
Google Scholar
[7] Wei H F, Chen S P, Hou J, Chen K K, Li J Y 2016 Chin. Phys. Lett. 33 64202
Google Scholar
[8] Boivin M, El-Amraoui M, Ledemi Y, Celarie F, Vallee R, Messaddeq Y 2016 Opt. Mater. Express 6 1653
Google Scholar
[9] Rezvani S A, Nomura Y, Ogawa K, Fuji T 2019 Opt. Express 27 24499
Google Scholar
[10] Li G, Peng X, Dai S, Wang Y, Xie M, Yang L, Yang C, Wei W, Zhang P 2018 J. Lightwave Technol. 37 1847
Google Scholar
[11] Zhang B, Yu Y, Zhai C, Qi S, Wang Y, Yang A, Gai X, Wang R, Yang Z, Luther-Davies B 2016 J. Am. Ceram. Soc. 99 2565
Google Scholar
[12] Zhao Z, Wu B, Wang X, Pan Z, Liu Z, Zhang P, Shen X, Nie Q, Dai S, Wang R 2017 Laser Photonics Rev. 11 1700005
Google Scholar
[13] Dai S, Wang Y, Peng X, Zhang P, Wang X, Xu Y 2018 Appl. Sci. 8 707
Google Scholar
[14] Yao C, Jia Z, Li Z, Jia S, Zhao Z, Zhang L, Feng Y, Qin G, Ohishi Y, Qin W 2018 Optica 5 1264
Google Scholar
[15] Gattass R R, Shaw L B, Nguyen V Q, Pureza P C, Aggarwal I D, Sanghera J S 2012 Opt. Fiber Technol. 18 345
Google Scholar
[16] Robichaud L R, Duval S, Pleau L P, Fortin V, Bah S T, Chatigny S, Vallee R, Bernier M 2020 Opt. Express 28 107
Google Scholar
[17] Zhang M, Li T, Yang Y, Tao H, Zhang X, Yuan X, Yang Z 2019 Opt. Mater. Express 9 555
Google Scholar
[18] You C, Dai S, Zhang P, Xu Y, Wang Y, Xu D, Wang R 2017 Sci. Rep. 7 6497
[19] Zhu L, Yang D, Wang L, Zeng J, Zhang Q, Xie M, Zhang P, Dai S 2018 Opt. Mater. 85 220
Google Scholar
[20] Zhang Y, Xu Y, You C, Xu D, Tang J, Zhang P, Dai S 2017 Opt. Express 25 8886
Google Scholar
[21] Messaddeq S H, Vallee R, Soucy P, Bernier M, El-Amraoui M, Messaddeq Y 2012 Opt. Express 20 29882
Google Scholar
[22] 李铜铜, 张鸣杰, 田康振, 张翔, 袁孝, 杨安平, 杨志勇 2019 光学学报 39 1016001
Google Scholar
Li T T, Zhang M J, Tian K Z, Zhang X, Yuan X, Yang A P, Yang Z Y 2019 Acta Opt. Sin. 39 1016001
Google Scholar
[23] Zhang M, Li L, Li T, Wang F, Tian K, Tao H, Feng X, Yang A, Yang Z 2019 Opt. Express 27 29287
Google Scholar
[24] Sun M, Yang A, Zhang X, Ma H, Zhang M, Tian K, Feng X, Yang Z 2019 J. Am. Ceram. Soc. 102 6600
Google Scholar
[25] Zhang M, Yang Z, Zhao H, Yang A, Li L, Tao H 2017 J. Alloys Compd. 722 166
Google Scholar
[26] Lu X, Lai Z, Zhang R, Guo H, Ren J, Strizik L, Wagner T, Farrell G, Wang P 2019 J. Eur. Ceram. Soc. 39 3373
Google Scholar
[27] 乔北京, 陈飞飞, 黄益聪, 戴世勋, 聂秋华, 徐铁峰 2015 物理学报 64 154216
Google Scholar
Qiao B J, Chen F F, Huang Y C, Dai S X, Nie Q H, Xu T F 2015 Acta Phys. Sin. 64 154216
Google Scholar
[28] Liu L, Zheng X, Xiao X, Xu Y, Cui X, Cui J, Guo C, Yang J, Guo H 2019 Opt. Mater. Express 9 3582
Google Scholar
[29] 杨艳, 陈云翔, 刘永华, 芮扬, 曹烽燕, 杨安平, 祖成奎, 杨志勇 2016 物理学报 65 127801
Google Scholar
Yang Y, Chen Y X, Liu Y H, Rui Y, Cao F Y, Yang A P, Zu C K, Yang Z Y 2016 Acta Phys. Sin. 65 127801
Google Scholar
[30] Yang Y, Zhang B, Yang A, Yang Z, Lucas P 2015 J. Phys. Chem. B 119 5096
Google Scholar
[31] Zhang B, Guo W, Yu Y, Zhai C, Qi S, Yang A, Li L, Yang Z, Wang R, Tang D, Tao G, Luther-Davies B 2015 J. Am. Ceram. Soc. 98 1389
Google Scholar
[32] Snopatin G E, Shiryaev V S, Plotnichenko V G, Dianov E M, Churbanov M F 2009 Inorg. Mater. 45 1439
Google Scholar
[33] Nguyen V Q, Sanghera J S, Kung F H, Aggarwal I D, Lloyd I K 1999 Appl. Opt. 38 3206
Google Scholar
[34] Dudley J M, Genty G, Coen S 2006 Rev. Mod. Phys. 78 1135
Google Scholar
[35] Biancalana F, Skryabin D V, Yulin A V 2004 Phys. Rev. E 70 016615
Google Scholar
[36] Eftekhar M A, Wright L G, Mills M S, Kolesik M, Correa R A, Wise F W, Christodoulides D N 2017 Opt. Express 25 9078
Google Scholar
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