Single-Mode Lasing in Plasmonic-Enhanced Woven Microfibers for Multifunctional Sensing

Zhang, Shuai; Shi, Xiaoyu; Yan, Shaoxin; Zhang, Xiao; Ge, Kun; Han, Chang Bao; Zhai, Tianrui

doi:10.1021/acssensors.1c01278

Cited by 11 publications

(5 citation statements)

References 52 publications

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“…Some of these include nanorods [92][93][94], nanowires [95][96][97][98][99], nanosheets [100][101][102], nanotubes [103,104], fullerenes [105,106], TM dichalcogenides, [107,108] hexagonal boron nitride [109,110], and core-shells [111][112][113]. Studies focussing on the integration of nanomaterials in plasmonics for sensing applications have led to breakthrough technologies such as wearable plasmonic sensors [114,115] and multi-parameter sensing [116][117][118]. Apart from heterostructures with nanomaterials, some plasmonic nanomaterials have also been reviewed in the literature [62,119].…”

Section: Nanomaterials Plasmonicsmentioning

confidence: 99%

Plasmonic gas sensors based on nanomaterials: mechanisms and recent developments

Vaidyanathan,

Mondal,

Rout

et al. 2024

J. Phys. D: Appl. Phys.

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Sensing devices for rapid analytics are important societal requirements, with wide applications in environmental diagnostics, food testing, and disease screening. Nanomaterials present excellent opportunities in sensing applications owing to their superior structural strength, and their electronic, magnetic, and optoelectronic properties. Among the various mechanisms of gas sensing, including chemiresistive sensors, electrochemical sensors, and acoustic sensors, another promising area in this field involves plasmonic sensors. The advantage of nanomaterial-plasmonic sensors lies in the vast opportunities for tuning the sensor performance by optimizing the nanomaterial structure, thereby producing highly selective and sensitive sensors. Recently, several novel plasmonic sensors have been reported, with various configurations such as nanoarray resonator-, ring resonator-, and fiber-based plasmonic sensors. Going beyond noble metals, some promising nanomaterials for developing plasmonic gas sensor devices include two-dimensional materials, viz. graphene, transition metal dichalcogenides, black phosphorus, blue phosphorus, and MXenes. Their properties can be tuned by creating hybrid structures with layers of nanomaterials and metals, and the introduction of dopants or defects. Such strategies can be employed to improve the device performance in terms of its dynamic range, selectivity, and stability of the response signal. In this review, we have presented the fundamental properties of plasmons that facilitate its application in sensor devices, the mechanism of sensing, and have reviewed recent literature on nanomaterial-based plasmonic gas sensors. This review briefly describes the status quo of the field and future prospects.

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Section: Nanomaterials Plasmonicsmentioning

confidence: 99%

Plasmonic gas sensors based on nanomaterials: mechanisms and recent developments

Vaidyanathan,

Mondal,

Rout

et al. 2024

J. Phys. D: Appl. Phys.

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show abstract

“…[133,265,266,[307][308][309] We expect that such lasing effects can be further engineered by increasing the complexity, for example, metal alloys for enhanced scattering or incorporating additional functionalities and/or reducing the symmetry (e.g., more anisotropic or chiral) and that they find many potential applications, including in sensing and active displays. [251,310,311] Recent advances in hybrid plasmonic systems and their large-scale fabrication, often utilizing shadow growth methods, accelerate the translation of current research activities into the industrial domain for real-world applications.…”

Section: Nanophotonic Devicesmentioning

confidence: 99%

Plasmonic Nanostructure Engineering with Shadow Growth

Han

Kim

et al. 2022

Advanced Materials

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Physical shadow growth is a vacuum deposition technique that permits a wide variety of 3D‐shaped nanoparticles and structures to be fabricated from a large library of materials. Recent advances in the control of the shadow effect at the nanoscale expand the scope of nanomaterials from spherical nanoparticles to complex 3D shaped hybrid nanoparticles and structures. In particular, plasmonically active nanomaterials can be engineered in their shape and material composition so that they exhibit unique physical and chemical properties. Here, the recent progress in the development of shadow growth techniques to realize hybrid plasmonic nanomaterials is discussed. The review describes how fabrication permits the material response to be engineered and highlights novel functions. Potential fields of application with a focus on photonic devices, biomedical, and chiral spectroscopic applications are discussed.

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“…By confining the complex disordered medium inside the microcavity, the output of the microcavity laser will exhibit a variety of complex characteristics as the disorder degree of the cavity boundary and the internal medium changes [15][16][17][18]. Disordered microcavities can induce quantum and photon confinement, Photonics 2024, 11, 467 2 of 12 offering broad application prospects in optical integration, optical interconnections, optical neural networks, optical display, and optical communications [19][20][21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Boundary Feedback Fiber Random Microcavity Laser Based on Disordered Cladding Structures

Zhu,

Zhao,

Liu

et al. 2024

Photonics

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The cavity form of complex microcavity lasers predominantly relies on disordered structures, whether found in nature or artificially prepared. These structures, characterized by disorder, facilitate random lasing through the feedback effect of the cavity boundary and the internal scattering medium via various mechanisms. In this paper, we report on a random fiber laser employing a disordered scattering cladding medium affixed to the inner cladding of a hollow-core fiber. The internal flowing liquid gain establishes a stable liquid-core waveguide environment, enabling long-term directional coupling output for random laser emission. Through theoretical analysis and experimental validation, we demonstrate that controlling the disorder at the cavity boundary allows liquid-core fiber random microcavities to exhibit random lasing output with different mechanisms. This provides a broad platform for in-depth research into the generation and control of complex microcavity lasers, as well as the detection of scattered matter within micro- and nanostructures.

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Single-Mode Lasing in Plasmonic-Enhanced Woven Microfibers for Multifunctional Sensing

Cited by 11 publications

References 52 publications

Plasmonic gas sensors based on nanomaterials: mechanisms and recent developments

Plasmonic gas sensors based on nanomaterials: mechanisms and recent developments

Plasmonic Nanostructure Engineering with Shadow Growth

Boundary Feedback Fiber Random Microcavity Laser Based on Disordered Cladding Structures

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