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东北师范大学 紫外光发射材料与技术教育部重点实验室, 吉林 长春 130024
[ "付申成(1979-),男,吉林省吉林市人,博士,教授,博士生导师,2010年于长春理工大学获得博士学位,主要从事光全息技术、光致变色功能材料与器件的研究。E-mail: fusc515@nenu. edu. cn" ]
[ "刘益春(1962-),男,吉林辉南人,博士,教授,博士生导师,中国科学院院士,1995年于中国科学院长春物理研究所与意大利都灵工业大学联合培养获得博士学位,主要从事氧化物半导体光电功能材料与器件的研究。E-mail: ycliu@nenu. edu. cn 刘益春,《发光学报》副主编,教授/博士生导师,中国科学院院士。第七届教育部科技委数理学部委员,国务院学位委员会第八届学科评议组成员,国际发光会议(ICL)程委会委员(2020大会主席),国际Ⅱ⁃Ⅵ族化合物材料会议顾委会委员,中国科学院BR计划,国家杰出青年科学基金获得者,教育部跨世纪优秀人才。1985年7月毕业于东北师范大学物理学院(原物理系),获理学学士学位;1988年6月毕业于中国科学院长春物理研究所凝聚态物理专业,获理学硕士学位;1995年12月于中国科学院长春物理研究所与意大利都灵工业大学联合培养凝聚态物理专业博士研究生毕业,获理学博士学位;曾在吉林大学化学系、日本九州大学先端科学技术研究中心做博士后。主要从事氧化物半导体光电功能材料与器件研究。" ]
纸质出版日期:2023-07-05,
收稿日期:2023-04-17,
修回日期:2023-05-09,
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付申成,刘益春.室温全息光谱烧孔:实现路径与研究展望[J].发光学报,2023,44(07):1123-1130.
FU Shencheng,LIU Yichun.Room-temperature Holographic Spectral Hole-burning: Implementation Path and Research Prospect[J].Chinese Journal of Luminescence,2023,44(07):1123-1130.
付申成,刘益春.室温全息光谱烧孔:实现路径与研究展望[J].发光学报,2023,44(07):1123-1130. DOI: 10.37188/CJL.20230086.
FU Shencheng,LIU Yichun.Room-temperature Holographic Spectral Hole-burning: Implementation Path and Research Prospect[J].Chinese Journal of Luminescence,2023,44(07):1123-1130. DOI: 10.37188/CJL.20230086.
光谱烧孔型全息存储因高密度、抗干扰、低能耗的特点而具备了海量“冷数据”存储潜力。本文结合作者的科研经历,首先简要回顾了光谱烧孔的发展历程和存在瓶颈;随后基于等离激元光谱烧孔的基本原理,阐述了过渡金属氧化物/贵金属功能基元室温全息光谱烧孔的新思想;继而展示了作者在大面积全息盘片研制和小型化全息存储器开发方面的最新成果;最后对未来利用功能基元空间序构实现高密度频域全息光谱烧孔进行了展望。作者所在团队的系列工作开辟了高密度光存储的新方向,同时为发展过渡金属氧化物基高集成光电器件提供了有益的思路。
Spectral hole-burning holographic storage has the characteristics of high-density, anti-interference and low-energy-consumption, and has potential ability of storing massive “cold data”. Based on our own research experience, we briefly review the development process and existing bottlenecks of spectral hole-burning. We propose a new idea to achieve room-temperature holographic spectral hole-burning in a functional unit of transition-metal-oxide/noble-metal, which is based on the principle of plasmatic spectral hole-burning. Then we present the latest achievements in large-area holographic discs and compact-type holographic memory devices. We also have a prospect for future work on high-density holographic spectral hole-burning in frequency domain
via
orderly arrangement of functional units. A series of work of the author's group open up a new direction for high-density optical storage, and provide a useful idea for the development of transition-metal-oxide-based optoelectronic devices with high-integration.
光谱烧孔过渡金属氧化物等离激元全息存储
spectral hole-burningtransition-metal-oxideplasmonholographic storage
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