Marvin Ma
1
Personal Information
Personal Information
E-Mail:
003154@nuist.edu.cnSchool/Department:
物理与光电工程学院(公共物理教学部)Education Level:
With Certificate of Graduation for Doctorate StudyDegree:
Doctoral Degree in EngineeringTeacher College:
School of Physics and Optoelectronic Engineering
Other Contact Information
ZipCode:210044
PostalAddress:藕舫楼313
Email:mayouqiao188@hotmail.com
Profile
课题组简介
想揭开“衍射极限”的神秘面纱吗?想超越所谓“衍射极限”吗?想在纳米尺度下去操控光子吗?
那么,不妨先来了解一下前沿纳米光子学---表面等离子体光学。
随着现代信息科学的高速发展,纯电子学器件由于自身固有局限难以满足传输与存储所需的高数据流。而光子具备传输速度快、易实现多路通信等优点,成为新一代信息传递的理想载体。然而,传统光学器件由于面临衍射极限的限制难以实现纳米量级集成化。
利用表面等离子体光学技术可解决上述技术问题。
表面等离子体(简称SPs),是入射光子与金属表面自由电子振荡频率一致时,相互作用而发生集体振荡在金属与介质分界面形成的一种混合电磁模式,它兼而具备光子的超高速和电子的衍射无限制特性,能够实现对电磁波的亚波长局域(i.e. 模式面积远小于l2/4),并伴有显著的电磁场增强特性。利用SPs独特结构依赖的色散敏感特性,可实现对电磁波振幅、偏振、相位、传输等多维度操控,为近场纳米光刻、超分辨成像、集成光子器件及光路的发展提供创造性技术突破。同时,由于SPs衰逝场模径大小与绝大多数生物细胞尺寸匹配,加上其显著的场增强效应,SPs光子技术也能够为表面增强拉曼散射、生物传感检测等研究提供重要应用价值。
针对上述研究问题和潜力,本课题组将致力于以下方面的研究:
● 集成光子器件设计与开发
● 二维材料结构设计与性能预测
● 激光与纳米粒子相互作用:光镊、光子操控、量子点荧光效应等。
● 生物光子学:结合SPs和光纤技术,实现抗原抗体检测、癌症标志物识别等。
同时本课题组也致力于光纤传感及光纤器件的研究!
项目参与者将收获:
1. 掌握电磁仿真模拟技术:有限元分析法(FEM),有限时域差分分析法(FDTD)等。
2. 熟悉微纳光学测试技术:光学测试光路搭建、扫描电子显微镜(SEM)、原子力显微镜等。
3. 掌握微纳加工制备技术:聚焦离子束刻蚀(FIB),电子束曝光刻蚀(EBL),干湿法刻蚀、原子层沉积镀膜技术等。
4. 其他:团队合作能力,科研能力,项目执行能力,科技撰写汇报能力等。
5. 提供国际合作(美国、加拿大、英国、日本、爱尔兰)交流机会。
欢迎有信心、有梦想、奋斗实干的同学加入课题组!
请联系:马佑桥
团队新闻
1. 2022.08-恭喜姜成凯同学在ACS Photonics期刊发表论文:
Spin–Orbit-Engineered Selective Transport of Photons in Plasmonic Nanocircuits with Panda-Patterned Transporters
论文连接:https://pubs.acs.org/doi/10.1021/acsphotonics.2c00841
2. 2022.08-团队“微光芯探”项目获2022年“创业江苏”科技创业大赛行业赛总决赛“优秀团队”;
创新创业大赛成果
■ 2022年,“创业江苏”科技创业大赛行业赛总决赛“优秀团队”(团队组);
■ 2021年,“赢在六合(南京) 创聚未来”青年大学生创业大赛优胜奖(指导老师);
■ 2021年,南京信息工程大学第七届“互联网+”大学生创新创业大赛铜奖(指导老师);
■ 2021年,南京信息工程大学第十七届“挑战杯”全国大学生科技作品竞赛二等奖(指导老师);
■ 2021年,南京信息工程大学生创新创业项目3项(指导老师);
■ 2020年,全国大学生光电设计竞赛全国总决赛三等奖(指导教师);
■ 2020年,南京江北新区高价值专利培育大赛优秀奖;
■ 2020年,江苏省大学生创新创业项目1项(指导老师);
全部论文详见谷歌学术: Youqiao Ma - Google Scholar
期刊论文
X. Y. Jin, J. H. Li, Y. Ma, Y. Q. Ma(通讯),Design of high-sensitive plasmonic sensors with circle-semi-ring coupled resonators, Optical and Quantum Electronics, 55:104, 2023.
C. K. Jiang, Z. Deng, B. Liu, J. H. Li, Z. H. Han, Y. Ma, D. Wu, H. Maeda, Y. Q. Ma(通讯), Spin–Orbit-Engineered Selective Transport of Photons in Plasmonic Nanocircuits with Panda-Patterned Transporters, ACS Photonics, 9, 3089-3093, 2022.
Y. Q. Ma, B. Liu, Z. Q. Huang, J. H. Li, Z. H. Han, D. Wu, J. Zhou, Y. Ma, Q. Wu, H. Maeda, High-direcionality spin-selective routing of photons in plasmonic nanocircuits, Nanoscale, 14, 428-432, 2022.
C.K.Jiang, J.H.Li,Z.H.Han, Y.Ma, Y. Q. Ma(通讯), Coupling of plasmon excited by single quantum emitters incorporated with metal nanoapertures, Optik, 250, 168323, 2022.
Y. Q. Ma, C.K.Jiang, K.L.Sun,B.Liu,J.H.Li,Z.H.Han,X.Hu,Y.Ma,Spin-orbit-enabled sorting of optical flows in plasmonic nanocircuits, Optics Letters, 46, 5675-5678, 2021.
X. Z. kong, J. H. Li, Y. Q. Ma(通讯), All-dielectric graphene-induced waveguide electro-optic modulators with offset nanowires, Optical Engineering, 60(10), 105103, 2021.
孔祥壮,李金花,罗晓曼,姜成凯,韩张华,马佑桥(通讯),基于偏置纳米线的石墨烯表面等离激元调制器,光学学报,41(19), 1923001, 2021.
Y. Q. Ma, J. H. Li, Z. H. Han, H. Maeda and J. Pištora, All-Dielectric Graphene-induced T-Slot Waveguide Electro-Optic Modulator with Polarization-Independent Operation, IEEE Journal of Selected Topics in Quantum Electronics, 27(3), 3400708, 2021.
Y. Q. Ma, J. H. Li, M. Cada, Y. S. Bian, Z. H. Han, Y. Ma, M. Iqbal and J. Pištora, Plasmon Generation and Routing in Nanowire-based Hybrid Plasmonic Coupling Systems with Incorporated Nanodisk Antennas, IEEE Journal of Selected Topics in Quantum Electronics, 27(1): 4600307, 2021.
Y. Q. Ma, J. H. Li, Z. H. Han, H. Maeda and Y. Ma, Bragg-Mirror-Assisted High-Contrast Plasmonic Interferometers: Concept and Potential in Terahertz Sensing, Nanomaterials, 1385(10), 2020.
Y. Q. Ma, J. H. Li and H. Maeda, Polarization-independent hybrid plasmonic coupler based on T-shaped slot waveguide, AIP Advances, 035121(10), 2020.
Y. Q. Ma, J. H. Li, G. G. Zheng, H. Xiao, Y. Ma and H. Maeda, Semiconductor THz microsensors based on ultrahigh-contrast T-shape patterned interferometers, Applied Physics Express, 017003(13) 2019.
Y. Q. Ma,D. Guo, Y. L. Gao, S. Sarah, Q. Wu, J. Zhou, J.Pištora and M.Cada, High Sensitive Z-shaped Fiber Interferometric Refractive Index Sensor: Simulation and Experiment, IEEE Photonics Technology Letters, 1131-1134(30), 2018.
Y. Q. Ma, Y. Alattar, J. Zhou, M.Eldlio, H. Maeda, J. Pištoraand M.Cada, Semiconductor-based plasmonic interferometers for ultrasensitive sensing in a terahertz regime, Optics Letters, 2338-2341(42), 2017.
Y. Q. Ma, N. Nguyen-Huu, J. Zhou, H. Maeda, Q. Wu, M.Eldlio, J. Pištoraand M.Cada, Mach-Zehnder Interferometer-based Integrated Terahertz Temperature Sensor, IEEE Journal of Selected Topics in Quantum Electronics, 1-7(23), 2017.
Y. Q. Ma, J. Zhou, J.Pištora, M.Eldlio, N. Nguyen-Huu, H. Maeda, Q. Wu, and M.Cada, Subwavelength InSb-based Slot wavguides for THz transport: concept and practical implementations, Scientific Reports, 38784(6), 2016.
Y. Q. Ma,M.Eldlio, H. Maeda, J. Zhou and M.Cada, Plasmonic properties of superconductor-insulator-superconductor waveguide, Applied Physics Express, 072201(9), 2016.
Y. Q. Ma, G. Farrell, Y.Semenova, B. H. Li, J. H. Yuan, C. X. Yu and Q. Wu, Optical nanofiber-loaded surface plasmonic TE-pass polarizer, Optics and Laser Technology, 101-105(78), 2016.
Y. Q. Ma, G. Farrell, Y.Semenova, and Q. Wu, A hybrid wedge-to-wedge plasmonic waveguide with low loss propagation and ultra-deep-nanoscale mode confinement, IEEE Journal of Lightwave Technology, 33 (18), 3827-3835, 2015.
Y. Q. Ma, G. Farrell, Y.Semenova, and Q. Wu, Hybrid nanowedge plasmonic waveguide for low loss propagation with ultra-deep-subwavelength mode confinement, Optics letters, 39 (4), 973-976, 2014.
Y. Q. Ma, G Farrell, Y Semenova, HP Chan, H Zhang, Q Wu, Sensitivity enhancement for a multimode fiber sensor with an axisymmetric metal grating layer, Photonics and Nanostructures-Fundamentals and Applications, 12 (1), 69-74, 2014.
Y. Q. Ma, G Farrell, Y Semenova, HP Chan, H Zhang, Q Wu, Low loss, high extinction ratio and ultra-compact plasmonic polarization beam splitter, IEEE Photonics Technology Letters, 26(7), 660-663, 2014.
Y. Q. Ma, G Farrell, Y Semenova, HP Chan, Q Wu, Hybrid plasmonic biosensor for simultaneous measurement of both thickness and refractive index, Infrared Physics & Technology, 60, 134-136, 2013.
Y. Q. Ma, G Farrell, Y Semenova, HP Chan, H Zhang, Q Wu, Novel dielectric-loaded plasmonic waveguide for tight-confined hybrid plasmon mode, Plasmonics, 8 (2), 1259-1263, 2013.
Y. Q. Ma, G. Farrell, Y.Semenova, and Q. Wu, Analysis and applications of nanocavity structures used as tunable filters and sensors, Infrared Physics & Technology, 55 (5), 389-394, 2012.
Y. Q. Ma, J Zhou, Z Wang, Surface plasmon waves on structured metal surface with periodic grooves modified by perpendicular cuts, IEEE Photonics Technology Letters, 22 (7), 450-452, 2010.
会议论文
Y. Q. Ma, Y. Alattar, M. Eldlio, N. Nguyen-Huu, H. Maeda, and M. Cada,Plasmonic Semiconductor-Based Interferometers for Ultrasensitive THz Biosensing,IEEE International Conference on Computational Electromagnetics, Japan, Oral presentation (2017).
Y. Q. Ma, M.Eldlio, H. Maedaand M.Cada, Analysis of Superconductor based Waveguide at THz and Telecommunication frequencies, Photonics North 2016, Canada (2016).
Y. Q. Ma, G. Farrell, Y.Semenova and Q. Wu, Hybrid waveguide based long range suface plasmon biosensor, SPIE Nanoscience+Engineering, San Diego, California, United States, Oral presentation (2013).
Y. Q. Ma, G. Farrell, Y.Semenova and Q. Wu, Novel Bragg Reflector and High-Q Cavity based on Dielectric Loaded Plasmonic Waveguide,Photonics Ireland, 4th -6th, Belfast, UK (2013).
Y. Q. Ma, G. Farrell, Y.Semenova, H. P. Chan and Q. Wu, High sensitivity refractive index sensor based on multimode fiber coated with axisymmetric metal grating layer, Asia Communications and Photonics Conference, Guangzhou, China (2012).
Y. Q. Ma, G. Farrell, Y.Semenova, H. P. Chan and Q. Wu, A Novel Biosensor based on a Coupled Surface Plasmon Nanostructure, Optical fiber sensors, Beijing, China (2012).
Y. Q. Ma, G. Farrell, Y.Semenova and Q. Wu, A Novel Nano-Plasmonic band-gap Splitter based on a T-shaped Bragg Grating Waveguide, SPIE Photonics Europe, 16th-19th Apr 2012, Brussels, Belgium (2012).
Y. Q. Ma, Q. Wu, Y. Semenova and G. Farrell, The influence of the structure of a sub-wavelength metal grating on its transmission efficiency,Photonics Ireland, 7th -9th Sep. 2011,Dublin, Ireland (2011).
专利(已授权)
马佑桥,姜成凯,李金花,一种光子自旋定向耦合器,ZL202210932545.0;
马佑桥,吴嘉骏,李金花,一种基于环形分裂共振腔的高灵敏集成传感器,ZL202221953819.6;
马佑桥,姜成凯,李金花,一种增强量子点发光的谐振激励结构,ZL202122713171.7;
马佑桥,李金花,任海东,一种光子自旋定向分离器,ZL202111083708.4;
马佑桥,孔祥壮,李金花,一种基于偏置全介质纳米线的石墨烯光学调制器,ZL202021791017.0;
马佑桥,卢贤,李金花,葛孝心,一种T型Slot光波导石墨烯表面等离子体调制器结构,ZL202023171727.6;
马佑桥,表面等离子共振生物检测信息提取分析软件V1.0,2021SR0670284,软件著作权;
马佑桥,一种基于抛物面反光镜的简化棱镜SPR激发装置,CN109799209A;
马佑桥,一种基于波导耦合表面等离子体共振传感芯片,CN109827932A;
马云燕,马佑桥,艾华,束鑫,一种基于亚波长金属V槽超强光束缚的表面等离子体波导,CN105467517A;
马云燕,马佑桥,陈立君,束鑫,基于表面等离子体的多模光纤探针生物传感装置,CN105136747B;
周骏, 马佑桥, 丁海芳, 马伟涛, 冯亚萍, 刘晓,一种测量介质热光系数和热膨胀系数的装置及方法,CN101441174B;
周骏, 马佑桥, 金嫦香, 徐丙振, 诸跃进,一种介质热光系数和热膨胀系数的测量装置,CN201314897Y;
李宏伟,冷志鹏,马佑桥,一种基于等强度梁的光纤布拉格光栅压力传感器,CN201772960U;
李宏伟,冷志鹏,马佑桥,一种光纤布拉格光栅压力传感器及其相应的测量方法,CN101900616B;
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