个人信息Personal Information
教授
博士生导师
硕士生导师
主要任职:光电工程与仪器科学学院院长、党委副书记
其他任职:辽宁省先进光电子技术重点实验室副主任,大连市新型功能材料与光电子器件重点实验室主任,中国超材料学会理事,中国机械工程学会极端制造分委员会委员,国际先进材料学会会士,Microsystems&Nanoengineering、chemosensors等期刊副编辑
性别:男
毕业院校:布里斯托尔大学
学位:博士
所在单位:光电工程与仪器科学学院
学科:光学工程. 电磁场与微波技术. 光学. 测试计量技术及仪器. 精密仪器及机械
办公地点:研教楼706
联系方式:0411-84706156
电子邮箱:caotun1806@dlut.edu.cn
Gate-Programmable Electro-Optical Addressing Array of Graphene-Coated Nanowires with Sub-10 nm Resolution
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论文类型:期刊论文
发表时间:2016-10-01
发表刊物:ACS PHOTONICS
收录刊物:SCIE、EI、Scopus
卷号:3
期号:10
页面范围:1847-1853
ISSN号:2330-4022
关键字:electro-optic addressing; sub-10 nm scale; graphene; phase matching; terahertz-wave generation
摘要:The rapid development of highly integrated photonic circuits has been driving electro-optic (EO) devices to increasingly compact sizes, with the perspective of being able to control light at the nanoscale. However, tunability with spatial resolution below 10 nm scale with conventional approaches, such as metallic nanowires, remains a challenge. Here, we show a graphene-coated nanowire system aiming at beam spatial modulation at a deeply subwavelength scale. By analytically and numerically investigating the eigenmodal properties of this system, we found that beam power can propagate along either a swinging or a helical path in the hybrid nanowire. In particular, the period of the swing beam and the chirality and period of the helix beam can be flexibly controlled by tuning the chemical potential of graphene via the gate voltage. Significantly, due to its good modal confinement, such a beam can be independently manipulated even in the presence of another nanowire at a separation of 40 nm, which opens a realistic path toward gate programmable EO addressing or data storage with ultrahigh density (64 terabyte/mu m). At the same time, by fulfilling the phase matching condition between the two supported guided modes operating at different wavelengths, either a full band or band tunable terahertz wave at the nanoscale may be achieved by nonlinear difference frequency generation. Our proposed hybrid nanowire system opens interesting potentials to accomplish gate-programmable EO devices at sub-10 nm scale.