基于石墨烯的有机光学太赫兹调制器

Bo Zhang, Guo-cui Wang, Hongyu Ji, Bin Li, Jing-ling Shen
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引用次数: 0

摘要

我们研究了一种高效的宽带太赫兹波调制器,其结构由共轭聚合物MEH - PPV,石墨烯和Si制成,用外部激发激光照射。我们展示了一种可以缓解聚合物/硅太赫兹波调制器中调制深度和调制速度要求之间权衡的策略。利用太赫兹时域和连续波系统,我们测量了调制器结构的太赫兹传输调制特性和时间响应。共轭聚合物/石墨烯/硅结构实现了93%的高传输调制因子,并提高了基于聚合物/硅的器件的调制速度。聚合物/石墨烯/硅结构的高调制效率分别来自载流子密度的增强和石墨烯极高的载流子迁移率。
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Graphene based Organic Optical Terahertz Modulator
We investigate a high-efficiency broadband terahertz wave modulator with structures made from the conjugated polymer MEH - PPV, graphene, and Si, irradiated with an external excitation laser. We demonstrate a strategy that can alleviate the tradeoffbetween the requirements of modulation depth and modulation speed in polymer/silicon terahertz wave modulators. Using terahertz time-domain and continuous-wave systems, we measured both the terahertz transmission modulation properties and the time responses of the modulator structures. The conjugated polymer/graphene/silicon structure achieved a high modulation factor of93% for transmission as well as improved the modulation speed of the devices based on polymer/silicon. The high modulation efficiency of the polymer/graphene/silicon structure was induced by the enhancement in carrier density and the extremely high carrier mobility of graphene, respectively.
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