The Roadmap of Graphene‐Based Optical Biochemical Sensors

Shivananju, Bannur Nanjunda; Yu, Wenzhi; Liu, Yan; Zhang, Yupeng; Lin, Bo; Li, Shaojuan; Bao, Qiaoliang

doi:10.1002/adfm.201603918

Cited by 77 publications

(51 citation statements)

References 82 publications

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“…There is growing interest in 2D materials, both fundamental and as potential parts in electronics and optoelectronics . Graphene, the first discovered 2D material, possesses ultrahigh mobility and good air stability, making it desirable for transistors applications .…”

Section: Angle Dependence Of the Raman Intensities Under Parallel Andmentioning

confidence: 99%

2D GeP: An Unexploited Low‐Symmetry Semiconductor with Strong In‐Plane Anisotropy

et al. 2018

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Germanium phosphide (GeP), a new member of the Group IV-Group V compounds, is introduced into the fast growing 2D family with experimental and theoretical demonstration of strong anisotropic physical properties. The indirect band gap of GeP can be drastically tuned from 1.68 eV for monolayer to 0.51 eV for bulk, with highly anisotropic dispersions of band structures. Thin GeP shows strong anisotropy of phonon vibrations. Moreover, photodetectors based on GeP flakes show highly anisotropic behavior with anisotropic factors of 1.52 and 1.83 for conductance and photoresponsivity, respectively. This work lays the foundation and ignites future research interests in Group IV-Group V compound 2D materials.

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Section: Angle Dependence Of the Raman Intensities Under Parallel Andmentioning

confidence: 99%

2D GeP: An Unexploited Low‐Symmetry Semiconductor with Strong In‐Plane Anisotropy

et al. 2018

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“…Graphene is commonly produced by exfoliation from graphite [28,29], epitaxial growth on SiC [30] or chemical vapor deposition (CVD) [31,32]. In particular, CVD produces uniform and large-scale graphene flakes of high-quality and is compatible with the silicon technology; therefore, it has been largely exploited to realize new electronic devices such as diodes [33][34][35][36], transistors [37][38][39], field emitters [40,41], chemical-biological sensors [42,43], optoelectronic systems [44], photodetectors [45][46][47][48][49][50] and solar cells [51].…”

Section: Introductionmentioning

confidence: 99%

Contact resistance and mobility in back-gate graphene transistors

et al. 2020

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The metal-graphene contact resistance is one of the major limiting factors toward the technological exploitation of graphene in electronic devices and sensors. High contact resistance can be detrimental to device performance and spoil the intrinsic great properties of graphene. In this paper, we fabricate back-gate graphene field-effect transistors with different geometries to study the contact and channel resistance as well as the carrier mobility as a function of gate voltage and temperature. We apply the transfer length method and the y-function method showing that the two approaches can complement each other to evaluate the contact resistance and prevent artifacts in the estimation of carrier mobility dependence on the gate-voltage. We find that the gate voltage modulates both the contact and the channel resistance in a similar way but does not change the carrier mobility. We also show that raising the temperature lowers the carrier mobility, has a negligible effect on the contact resistance, and can induce a transition from a semiconducting to a metallic behavior of the graphene sheet resistance, depending on the applied gate voltage. Finally, we show that eliminating the detrimental effects of the contact resistance on the transistor channel current almost doubles the carrier field-effect mobility and that a competitive contact resistance as low as 700 Ω·μm can be achieved by the zig-zag shaping of the Ni contact.

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“…In recent years, graphene gas sensors with microfibers develop rapidly, some of them are also reviewed in Refs. [ 81 , 82 , 83 , 84 ]. The roadmap demonstrates that the sensitivity of these graphene-based microfiber gas sensors increases from parts per kilo (ppk) to part per billion (ppb) by gradually optimizing the sensing structure.…”

Section: Graphene Gas Sensors With Microfibersmentioning

confidence: 99%

Optical Graphene Gas Sensors Based on Microfibers: A Review

Yao

et al. 2018

Sensors

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Graphene has become a bridge across optoelectronics, mechanics, and bio-chemical sensing due to its unique photoelectric characteristics. Moreover, benefiting from its two-dimensional nature, this atomically thick film with full flexibility has been widely incorporated with optical waveguides such as fibers, realizing novel photonic devices including polarizers, lasers, and sensors. Among the graphene-based optical devices, sensor is one of the most important branch, especially for gas sensing, as rapid progress has been made in both sensing structures and devices in recent years. This article presents a comprehensive and systematic overview of graphene-based microfiber gas sensors regarding many aspects including sensing principles, properties, fabrication, interrogating and implementations.

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The Roadmap of Graphene‐Based Optical Biochemical Sensors

Cited by 77 publications

References 82 publications

2D GeP: An Unexploited Low‐Symmetry Semiconductor with Strong In‐Plane Anisotropy

2D GeP: An Unexploited Low‐Symmetry Semiconductor with Strong In‐Plane Anisotropy

Contact resistance and mobility in back-gate graphene transistors

Optical Graphene Gas Sensors Based on Microfibers: A Review

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