High-Sensitivity Goos-Hänchen Shifts Sensor Based on BlueP-TMDCs-Graphene Heterostructure

Surface plasmon resonance (SPR) with two-dimensional (2D) materials is proposed to enhance the sensitivity of sensors. A novel Goos–Hänchen (GH) shift sensing scheme based on blue phosphorene (BlueP)/transition metal dichalogenides (TMDCs) and graphene structure is proposed. The significantly enhanced GH shift is obtained by optimizing the layers of BlueP/TMDCs and graphene. The maximum GH shift of the hybrid structure of Ag-Indium tin oxide (ITO)-BlueP/WS2–graphene is −2361λ with BlueP/WS2 four layers and a graphene monolayer. Furthermore, the GH shift can be positive or negative depending on the layer number of BlueP/TMDCs and graphene. For sensing performance, the highest sensitivity of 2.767 × 107λ/RIU is realized, which is 5152.7 times higher than the traditional Ag-SPR structure, 2470.5 times of Ag-ITO, 2159.2 times of Ag-ITO-BlueP/WS2, and 688.9 times of Ag-ITO–graphene. Therefore, such configuration with GH shift can be used in various chemical, biomedical and optical sensing fields.

[1]  Xifang Chen,et al.  Ultra-wideband solar absorber based on refractory titanium metal , 2020 .

[2]  Zao Yi,et al.  Study on the solar energy absorption of hybrid solar cells with trapezoid-pyramidal structure based PEDOT:PSS/c-Ge , 2020 .

[3]  Xinbing Jiao,et al.  Goos–Hänchen and Imbert–Fedorov shifts of a laser beam reflected from ITO under complex fields , 2020 .

[4]  Lei Han,et al.  Giant Goos-Hänchen Shifts in Au-ITO-TMDCs-Graphene Heterostructure and Its Potential for High Performance Sensor , 2020, Sensors.

[5]  Tianye Huang,et al.  Sensitivity Enhancement of Ag-ITO-TMDCs-Graphene Nanostructure Based on Surface Plasmon Resonance Biosensors , 2019, Plasmonics.

[6]  Tingting Tang,et al.  Electro-optic and magneto-optic modulations of Goos-Hänchen effect in double graphene coating waveguide with sensing applications , 2019 .

[7]  Yuanjiang Xiang,et al.  Enhanced and controllable Goos–Hänchen shift with graphene surface plasmon in the terahertz regime , 2019 .

[8]  Xinglin Zhou,et al.  Sensitivity enhancement of an SPR biosensor with a graphene and blue phosphorene/transition metal dichalcogenides hybrid nanostructure. , 2019, Applied optics.

[9]  D. Pudiš,et al.  Ultrahigh-sensitive plasmonic sensing of gas using a two-dimensional dielectric grating. , 2019, Optics letters.

[10]  Qian-Feng Zhang,et al.  Isolation and Structures of One- and Two-Dimensional High-Nuclearity Silver(I) Clusters from a Silver Propane-2-thiolate Chain , 2019, Journal of Cluster Science.

[11]  M. Tomita,et al.  Giant and highly reflective Goos-Hänchen shift in a metal-dielectric multilayer Fano structure. , 2019, Optics express.

[12]  Sameer Shrivastava,et al.  Surface plasmon resonance immunosensor for label-free detection of BIRC5 biomarker in spontaneously occurring canine mammary tumours , 2019, Scientific Reports.

[13]  Yunhan Luo,et al.  Surface plasmon resonance enhanced Goos–Hänchen and Imbert–Fedorov shifts of Laguerre–Gaussian beams , 2019, Optics Communications.

[14]  Zhaoming Luo,et al.  Precise control of positive and negative Goos-Hänchen shifts in graphene , 2019, Carbon.

[15]  Tianye Huang,et al.  Comprehensive Study of SPR Biosensor Performance Based on Metal-ITO-Graphene/TMDC Hybrid Multilayer , 2019, Plasmonics.

[16]  G. Usaj,et al.  Anomalous Goos-Hänchen shift in the Floquet scattering of Dirac fermions , 2019, Physical Review A.

[17]  Tingting Tang,et al.  Weak measurement of magneto-optical Goos-Hänchen effect. , 2019, Optics express.

[18]  Jiqing Lian,et al.  Broadband Absorption Tailoring of SiO2/Cu/ITO Arrays Based on Hybrid Coupled Resonance Mode , 2019, Nanomaterials.

[19]  Ziauddin,et al.  Giant negative and positive Goos–Hänchen shifts via Doppler broadening effect , 2019, Laser Physics.

[20]  J. Huguenin,et al.  Experimental evidence of laser power oscillations induced by the relative Fresnel (Goos–Hänchen) phase , 2019, Laser Physics Letters.

[21]  M. Jabbari,et al.  Enhancement of Goos–Hänchen shifts due to spontaneously generated coherence in a four-level Rydberg atom , 2019, Laser Physics.

[22]  Y. Prajapati,et al.  Performance Analysis of Silicon and Blue Phosphorene/MoS2 Hetero-Structure Based SPR Sensor , 2019, Photonic Sensors.

[23]  Jing Zhang,et al.  Large Tunable Lateral Shift from Guided Wave Surface Plasmon Resonance , 2019, Plasmonics.

[24]  Zheng Zheng,et al.  Effect of Excitation Beam Divergenceon the Goos–HänchenShift Enhanced byBloch Surface Waves , 2018, Applied Sciences.

[25]  Chuan Wu,et al.  A Phase Sensitivity-Enhanced Surface Plasmon Resonance Biosensor Based on ITO-Graphene Hybrid Structure , 2018, Plasmonics.

[26]  Yuanjiang Xiang,et al.  Giant and controllable Goos-Hänchen shifts based on surface plasmon resonance with graphene-MoS2 heterostructure , 2018, Optical Materials Express.

[27]  X. Dai,et al.  Giant Goos–Hänchen shifts of waveguide coupled long-range surface plasmon resonance mode , 2018, Chinese Physics B.

[28]  Songnian Fu,et al.  Broadband Optical Reflection Modulator in Indium-Tin-Oxide-Filled Hybrid Plasmonic Waveguide with High Modulation Depth , 2018, Plasmonics.

[29]  Yuancheng Fan,et al.  Broadband Terahertz Absorption in Graphene-Embedded Photonic Crystals , 2018, Plasmonics.

[30]  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.

[31]  Ankit Kumar Pandey,et al.  Blue Phosphorene/MoS2 Heterostructure Based SPR Sensor With Enhanced Sensitivity , 2018, IEEE Photonics Technology Letters.

[32]  F. J. Rodríguez-Fortuño,et al.  Directional scattering from particles under evanescent wave illumination: the role of reactive power. , 2018, Optics letters.

[33]  M. Hameed,et al.  Accurate calculation of Goos-Hänchen shift at critical angle for complex laser beam profiles using beam propagation method , 2018 .

[34]  F. Cheng,et al.  Effects of strain on Goos-Hänchen shifts of monolayer phosphorene , 2018 .

[35]  L. Gao,et al.  Enhanced normal-incidence Goos-Hänchen effects induced by magnetic surface plasmons in magneto-optical metamaterials. , 2018, Optics express.

[36]  Rajan Jha,et al.  Black Phosphorus: A New Platform for Gaseous Sensing Based on Surface Plasmon Resonance , 2018, IEEE Photonics Technology Letters.

[37]  Bing Wang,et al.  Giant Goos-Hänchen shifts in non-Hermitian dielectric multilayers incorporated with graphene. , 2018, Optics express.

[38]  S. Tretyakov,et al.  Systematic design and experimental demonstration of bianisotropic metasurfaces for scattering-free manipulation of acoustic wavefronts , 2017, Nature Communications.

[39]  Dianyuan Fan,et al.  Sensitivity enhancement by using few-layer black phosphorus-graphene/TMDCs heterostructure in surface plasmon resonance biochemical sensor , 2017 .

[40]  Zhimei Sun,et al.  Electronic structures and enhanced optical properties of blue phosphorene/transition metal dichalcogenides van der Waals heterostructures , 2016, Scientific Reports.

[41]  Sailing He,et al.  Sensitivity Enhancement of Transition Metal Dichalcogenides/Silicon Nanostructure-based Surface Plasmon Resonance Biosensor , 2016, Scientific Reports.

[42]  Xiang-Min Meng,et al.  Graphene–MoS2 hybrid nanostructures enhanced surface plasmon resonance biosensors , 2015 .

[43]  P. Stockschläder,et al.  Curvature dependence of semiclassical corrections to ray optics: How Goos-Hänchen shift and Fresnel filtering deviate from the planar case result , 2014 .

[44]  Zhen Zhu,et al.  Phase coexistence and metal-insulator transition in few-layer phosphorene: a computational study. , 2014, Physical review letters.

[45]  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.

[46]  Zhen Zhu,et al.  Semiconducting layered blue phosphorus: a computational study. , 2014, Physical review letters.

[47]  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.

[48]  Stefano Borini,et al.  Optical constants of graphene layers in the visible range , 2009 .

[49]  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 .

[50]  Banshi D. Gupta,et al.  Sensitivity evaluation of a multi-layered surface plasmon resonance-based fiber optic sensor: a theoretical study , 2005 .

[51]  Nicholas X. Fang,et al.  Large positive and negative lateral optical beam displacements due to surface plasmon resonance , 2004 .