Giant Goos-Hänchen Shifts in Au-ITO-TMDCs-Graphene Heterostructure and Its Potential for High Performance Sensor
暂无分享,去创建一个
Lei Han | Qizheng Ji | Jin Wang | Tianye Huang | Jianxing Pan | Chuan Wu | Keliang Li | Huafeng Ding | Ming Yang | Huijie Zhang | Tianye Huang | Huafeng Ding | Lei Han | Q. Ji | Jin Wang | Ming Yang | Chuan Wu | Jianxing Pan | Keliang Li | Huijie Zhang
[1] Yuancheng Fan,et al. Broadband Terahertz Absorption in Graphene-Embedded Photonic Crystals , 2018, Plasmonics.
[2] Tingting Tang,et al. Weak measurement of magneto-optical Goos-Hänchen effect. , 2019, Optics express.
[3] Zhenhua Wu,et al. Valley-dependent Brewster angles and Goos-Hänchen effect in strained graphene. , 2010, Physical review letters.
[4] Dianyuan Fan,et al. Sensitivity Enhanced by MoS2–Graphene Hybrid Structure in Guided-Wave Surface Plasmon Resonance Biosensor , 2018, Plasmonics.
[5] Jing Zhang,et al. Large Tunable Lateral Shift from Guided Wave Surface Plasmon Resonance , 2019, Plasmonics.
[6] Songnian Fu,et al. Broadband Optical Reflection Modulator in Indium-Tin-Oxide-Filled Hybrid Plasmonic Waveguide with High Modulation Depth , 2018, Plasmonics.
[7] Wenyi Ren,et al. Large tunable negative lateral shift from graphene-based hyperbolic metamaterials backed by a dielectric , 2018, Superlattices and Microstructures.
[8] Dianyuan Fan,et al. Sensitivity enhancement by using few-layer black phosphorus-graphene/TMDCs heterostructure in surface plasmon resonance biochemical sensor , 2017 .
[9] Hocine Bahlouli,et al. Effect of magnetic field on Goos-Hänchen shifts in gaped graphene triangular barrier , 2018, Physica E: Low-dimensional Systems and Nanostructures.
[10] Yuanjiang Xiang,et al. Enhanced and controllable Goos–Hänchen shift with graphene surface plasmon in the terahertz regime , 2019 .
[11] Arnolds Ubelis,et al. Application of 2D Non-Graphene Materials and 2D Oxide Nanostructures for Biosensing Technology , 2016, Sensors.
[12] Liang Tang,et al. Magnetic nanoparticle mediated enhancement of localized surface plasmon resonance for ultrasensitive bioanalytical assay in human blood plasma. , 2013, Analytical chemistry.
[13] Yuanjiang Xiang,et al. Giant and controllable Goos-Hänchen shifts based on surface plasmon resonance with graphene-MoS2 heterostructure , 2018, Optical Materials Express.
[14] Pawan K. Kulriya,et al. Blue-Shifted SPR of Au Nanoparticles with Ordering of Carbon by Dense Ionization and Thermal Treatment , 2013, Plasmonics.
[15] Hassan Ghadiri,et al. Gate-controlled valley transport and Goos–Hänchen effect in monolayer WS2 , 2017, Journal of physics. Condensed matter : an Institute of Physics journal.
[16] M. Pradhan,et al. Goos–Hänchen shift for Gaussian beams impinging on monolayer-MoS2-coated surfaces , 2018, Journal of the Optical Society of America B.
[17] Amy Q Shen,et al. Real-time monitoring of DNA immobilization and detection of DNA polymerase activity by a microfluidic nanoplasmonic platform. , 2019, Biosensors & bioelectronics.
[18] Sabine Szunerits,et al. Surface Plasmon Resonance Investigation of Silver and Gold Films Coated with Thin Indium Tin Oxide Layers: Influence on Stability and Sensitivity , 2008 .
[19] Xiang-Min Meng,et al. Graphene–MoS2 hybrid nanostructures enhanced surface plasmon resonance biosensors , 2015 .
[20] Anna Tsargorodska. Research and development in optical biosensors for determination of toxic environmental pollutants , 2007 .
[21] Minghong Yang,et al. A High-Sensitivity and Broad-Range SPR Glucose Sensor Based on Improved Glucose Sensitive Membranes , 2019, Photonic Sensors.
[22] Tianye Huang,et al. Comprehensive Study of Phase-Sensitive SPR Sensor Based on Metal–ITO Hybrid Multilayer , 2019, Plasmonics.
[23] Liberato Manna,et al. Tunable Near Infrared Localized Surface Plasmon Resonance of F, In co-doped CdO Nanocrystals. , 2019, ACS applied materials & interfaces.
[24] Xuejun Qiu,et al. A high-quality spin and valley beam splitter in WSe2 tunnelling junction through the Goos–Hänchen shift , 2019, Journal of physics. Condensed matter : an Institute of Physics journal.
[25] Sulaiman Wadi Harun,et al. Investigation of Surface Plasmon Resonance (SPR) in MoS2- and WS2-Protected Titanium Side-Polished Optical Fiber as a Humidity Sensor , 2019, Micromachines.
[26] Yuanjiang Xiang,et al. Tunable enhanced Goos–Hänchen shift of light beam reflected from graphene-based hyperbolic metamaterials , 2018 .
[27] J. Homola. Surface plasmon resonance sensors for detection of chemical and biological species. , 2008, Chemical reviews.
[28] Zheng Zheng,et al. Effect of Excitation Beam Divergenceon the Goos–HänchenShift Enhanced byBloch Surface Waves , 2018, Applied Sciences.
[29] Nak-Hyeon Kim,et al. Enhanced surface plasmon resonance detection using porous ITO–gold hybrid substrates , 2012 .
[30] Hassan Ghadiri,et al. Band-offset-induced lateral shift of valley electrons in ferromagnetic MoS2/WS2 planar heterojunctions , 2018, 1803.03811.
[31] R. V. Petrov,et al. Principle of tunable chemical vapor detection exploiting the angular Goos–Hänchen shift in a magneto-electric liquid-crystal-based system , 2017 .
[32] Sailing He,et al. Sensitivity Enhancement of Transition Metal Dichalcogenides/Silicon Nanostructure-based Surface Plasmon Resonance Biosensor , 2016, Scientific Reports.
[33] G. Solookinejad,et al. Giant Goos-Hänchen Shifts in Polaritonic Materials Doped with Nanoparticles , 2017, Plasmonics.
[34] Bahar Meshginqalam,et al. Performance Enhancement of SPR Biosensor Based on Phosphorene and Transition Metal Dichalcogenides for Sensing DNA Hybridization , 2018, IEEE Sensors Journal.
[35] Ananya Paul,et al. Biosensor-surface plasmon resonance: A strategy to help establish a new generation RNA-specific small molecules. , 2019, Methods.
[36] Chuan Wu,et al. A Phase Sensitivity-Enhanced Surface Plasmon Resonance Biosensor Based on ITO-Graphene Hybrid Structure , 2018, Plasmonics.
[37] Anna Olaison,et al. Handling the Dilemma of Self-Determination and Dementia: A Study of Case Managers’ Discursive Strategies in Assessment Meetings , 2015, Journal of gerontological social work.
[38] J. P. Woerdman,et al. Observation of Goos-Hänchen shifts in metallic reflection. , 2007, Optics express.
[39] Ahmed Jellal,et al. Goos-Hänchen shifts in graphene-based linear barrier , 2019, Materials Research Express.
[40] Sameer Shrivastava,et al. Surface plasmon resonance immunosensor for label-free detection of BIRC5 biomarker in spontaneously occurring canine mammary tumours , 2019, Scientific Reports.
[41] Tianye Huang,et al. Comprehensive Study of SPR Biosensor Performance Based on Metal-ITO-Graphene/TMDC Hybrid Multilayer , 2019, Plasmonics.
[42] M. Olivo,et al. Side-channel photonic crystal fiber for surface enhanced Raman scattering sensing , 2016 .
[43] Jiqing Lian,et al. Broadband Absorption Tailoring of SiO2/Cu/ITO Arrays Based on Hybrid Coupled Resonance Mode , 2019, Nanomaterials.
[44] Banshi D Gupta,et al. Surface plasmon resonance based fiber optic pH sensor utilizing Ag/ITO/Al/hydrogel layers. , 2013, The Analyst.
[45] Choon How Gan,et al. Analysis of surface plasmon excitation at terahertz frequencies with highly doped graphene sheets via attenuated total reflection , 2012, 1303.0438.
[46] Stefano Borini,et al. Optical constants of graphene layers in the visible range , 2009 .
[47] M. Daimon,et al. Measurement of the refractive index of distilled water from the near-infrared region to the ultraviolet region. , 2007, Applied optics.
[48] B. Majlis,et al. FDTD simulation of Kretschmann based Cr-Ag-ITO SPR for refractive index sensor , 2019, Materials Today: Proceedings.
[49] S Mariani,et al. Direct detection of genomic DNA by surface plasmon resonance imaging: an optimized approach. , 2013, Biosensors & bioelectronics.
[50] Satyendra Kumar Mishra,et al. Infrared SPR sensitivity enhancement using ITO/TiO2/silicon overlays , 2015 .
[51] Rajan Jha,et al. On the Performance of Highly Sensitive and Accurate Graphene-on-Aluminum and Silicon-Based SPR Biosensor for Visible and Near Infrared , 2014, Plasmonics.
[52] K. Artmann. Berechnung der Seitenversetzung des totalreflektierten Strahles , 1948 .
[53] Rajan Jha,et al. Black Phosphorus: A New Platform for Gaseous Sensing Based on Surface Plasmon Resonance , 2018, IEEE Photonics Technology Letters.
[54] Perry Shum Ping,et al. Sensitivity Enhancement in Surface Plasmon Resonance Biochemical Sensor Based on Transition Metal Dichalcogenides/Graphene Heterostructure , 2018, Sensors.