A mode field adapter (MFA) fabricated by the thermal expanded core (TEC) technique is investigated. Firstly, the mode field characteristics of the TEC large mode area fiber (LMAF) are analyzed. Compared with the...A mode field adapter (MFA) fabricated by the thermal expanded core (TEC) technique is investigated. Firstly, the mode field characteristics of the TEC large mode area fiber (LMAF) are analyzed. Compared with the single-mode fiber (SMF), the mode field diameter of the LMAF enlarged slower than that of the SMF. Secondly, the mode field characteristics of the different fibers with TEC treatment are discussed. Thirdly, the transmission efficiency of the MFA fabricated by the SMF and LMAF is also investigated. Finally, we used the 6/125 μm SMF and 15/130 μm LMAF to fabricate an MFA with transmission efficiency of 92% and the handling power as high as 100 W.展开更多
We have demonstrated a mode matching method between two different fibers by a hybrid thermal expanded core technique, which can be applied to match the modes of fiber-based Fabry–Pérot cavities. Experimentally, ...We have demonstrated a mode matching method between two different fibers by a hybrid thermal expanded core technique, which can be applied to match the modes of fiber-based Fabry–Pérot cavities. Experimentally, this method has achieved an expansion of the ultraviolet fiber core by 3.5 times while keeping fundamental mode propagation. With the experiment parameters, the fundamental mode coupling efficiency between the fiber and micro-cavity can reach 95% for a plano-concave cavity with a length of 400 μm. This method can not only have potential in quantum photonics research but also can be applied in classical optical fields.展开更多
采用预分散、常压悬浮聚合法制备以聚(丙烯腈-co-甲基丙烯酸酯)为外壳,异辛烷为芯材的微胶囊发泡剂(TEMs)。制备的TEMs壁厚均匀,呈现完整"核-壳"结构的球形,发泡性能良好。微胶囊发泡剂的平均粒径约28.5μm,粒径分布较窄,芯...采用预分散、常压悬浮聚合法制备以聚(丙烯腈-co-甲基丙烯酸酯)为外壳,异辛烷为芯材的微胶囊发泡剂(TEMs)。制备的TEMs壁厚均匀,呈现完整"核-壳"结构的球形,发泡性能良好。微胶囊发泡剂的平均粒径约28.5μm,粒径分布较窄,芯材含量约为23%,起始发泡温度98~120℃,发泡体积为4.5倍。文中研究了分散剂类型、单体和交联剂对微胶囊发泡剂的形貌和发泡性能的影响,使用无机分散剂(20 g Mg(OH)_2,70 g Na Cl,15 g MgCl_2)时,分散效果较好;当AN与MMA的质量比为1:1时,能得到球形较完整的TEMs;添加不同含量的1,4-丁二醇二甲基丙烯酸酯(BDDMA)交联剂时,包裹发泡剂的含量随着BDDMA含量的增加而减少,发泡温度随着BDDMA含量的增加而升高。展开更多
基金supported by the Shenzhen Peacock Plan(No.KQCX2015033110182368)the project of Shenzhen Science and Technology Innovation Committee(No.JCYJ20160301114759922)
文摘A mode field adapter (MFA) fabricated by the thermal expanded core (TEC) technique is investigated. Firstly, the mode field characteristics of the TEC large mode area fiber (LMAF) are analyzed. Compared with the single-mode fiber (SMF), the mode field diameter of the LMAF enlarged slower than that of the SMF. Secondly, the mode field characteristics of the different fibers with TEC treatment are discussed. Thirdly, the transmission efficiency of the MFA fabricated by the SMF and LMAF is also investigated. Finally, we used the 6/125 μm SMF and 15/130 μm LMAF to fabricate an MFA with transmission efficiency of 92% and the handling power as high as 100 W.
基金funding support from the National Key Research and Development Program of China (Nos. 2017YFA0304100, 2016YFA0302700)the National Natural Science Foundation of China (Nos. 11774335, 11474268, 11734015, 11821404)+2 种基金Key Research Program of Frontier Sciences, CAS (No. QYZDY-SSW-SLH003)the Fundamental Research Funds for the Central Universities (Nos. WK2470000026, WK2470000018)Anhui Initiative in Quantum Information Technologies (Nos. AHY020100, AHY070000)
文摘We have demonstrated a mode matching method between two different fibers by a hybrid thermal expanded core technique, which can be applied to match the modes of fiber-based Fabry–Pérot cavities. Experimentally, this method has achieved an expansion of the ultraviolet fiber core by 3.5 times while keeping fundamental mode propagation. With the experiment parameters, the fundamental mode coupling efficiency between the fiber and micro-cavity can reach 95% for a plano-concave cavity with a length of 400 μm. This method can not only have potential in quantum photonics research but also can be applied in classical optical fields.
文摘采用预分散、常压悬浮聚合法制备以聚(丙烯腈-co-甲基丙烯酸酯)为外壳,异辛烷为芯材的微胶囊发泡剂(TEMs)。制备的TEMs壁厚均匀,呈现完整"核-壳"结构的球形,发泡性能良好。微胶囊发泡剂的平均粒径约28.5μm,粒径分布较窄,芯材含量约为23%,起始发泡温度98~120℃,发泡体积为4.5倍。文中研究了分散剂类型、单体和交联剂对微胶囊发泡剂的形貌和发泡性能的影响,使用无机分散剂(20 g Mg(OH)_2,70 g Na Cl,15 g MgCl_2)时,分散效果较好;当AN与MMA的质量比为1:1时,能得到球形较完整的TEMs;添加不同含量的1,4-丁二醇二甲基丙烯酸酯(BDDMA)交联剂时,包裹发泡剂的含量随着BDDMA含量的增加而减少,发泡温度随着BDDMA含量的增加而升高。