Your search keyword '"Liu, Yundong"' showing total 5 results

1. First- and second-order SPP-mode co-induced dual-polarized refractive-index sensor based on photonic crystal fiber and gold film.

Author

Liu, Yundong and Chen, Hailiang

Subjects

*GOLD films, *REFRACTIVE index, *PHOTONIC crystal fibers, *LIQUID films, *PLASTIC optical fibers, *SURFACE plasmon resonance, *FINITE element method, *DETECTORS

Abstract

A dual-polarized photonic crystal fiber (PCF) sensor based on surface plasmon resonance (SPR) was proposed for measuring the refractive indexes (RIs) of liquids. A gold film and a liquid analyte were successively wrapped around the outer surface of the PCF to stimulate the external SPR effect, which greatly reduced the manufacturing difficulties, compared to depositing the gold film and filling the inner air holes of the PCF with liquid analyte. The performance of the proposed PCF sensor was numerically investigated using the finite-element method. The results show that the proposed PCF sensor can realize dual-polarized detection in the RI range of 1.36–1.42. The x and y polarization (X-P and Y-P) core modes were coupled to the X-P second-order and Y-P first-order surface-plasmon polariton modes, respectively. As the the RI of the analyte increased, the wavelength sensitivity increased and, as a result, maximum values of 15 900 nm RIU−1 for X-P and 16 900 nm RIU−1 for Y-P were achieved. Correspondingly, we obtained a maximum amplitude sensitivity of 2026.05 RIU−1 for X-P and 2102.65 RIU−1 for Y-P. In addition, the fabrication tolerance of the proposed PCF was increased to ±0.4 μm, which made the proposed PCF a favorable candidate for the detection of liquids. [ABSTRACT FROM AUTHOR]

Published

2021

2. A High-Sensitivity SPR Refractive Index Sensor Based on No-Core Fiber with Ag-Cu Composite Films.

Author

Feng, Yuhui, Li, Hongyu, Li, Shuguang, Liu, Yundong, and Meng, Xiaojian

Subjects

REFRACTIVE index, PLASTIC optical fibers, FIBROUS composites, SURFACE plasmon resonance, METALLIC films, DETECTORS

Abstract

A fiber/Ag-Cu films surface plasmon resonance (SPR) refractive index (RI) sensor composed of multimode fiber-no-core-fiber-multimode fiber (MMF-NCF-MMF) structure is designed. The sensing region length and Cu film deposition time of sensor are gradually optimized by the control variable method, which finally achieves the improvement of sensor properties. We experimentally compared the sensing performance of the fiber/Ag film and fiber/Ag-Cu films sensor. Experimental results show that the fiber/Ag-Cu films sensor has good linearity (R-square = 0.993), and its sensitivity is as high as 3957 nm/RIU in the refractive index detection range of 1.3328–1.3853, which is 1109 nm/RIU higher than the sensitivity of a conventional fiber/Ag film sensor. The sensor presented in this paper adopts the structure with composite metal film, which outperforms the common single-layer metal film in chemical stability such as oxidation resistance and mechanical hardness. Meanwhile, the SPR sensor with MMF-NCF-MMF structure has the advantages of convenient manufacture and compact structure. In conclusion, it can bestow a unique advantage in the field of biological detection or chemical analysis. [ABSTRACT FROM AUTHOR]

Published

2021

3. Ultrasensitive fiber-optic temperature sensor based on cascaded Sagnac interferometers with a nematic liquid crystal film.

Author

Fan, Xiaoya, Chen, Hailiang, Zheng, Yu, Liu, Yundong, Chen, Qiang, Zhang, Yingyue, Ma, Mingjian, Du, Huijing, Li, Shuguang, and Shum, Perry Ping

Subjects

*TEMPERATURE sensors, *LIQUID crystal films, *NEMATIC liquid crystals, *INTERFEROMETERS, *PLASTIC optical fibers, *OPTICAL fiber detectors, *FIBER optical sensors, *MAGNETIC devices

Abstract

• An ultrahigh-sensitive fiber-optic temperature sensor based on cascaded Sagnac interferometers with a nematic liquid crystal film was proposed and experimentally demonstrated. • The molecules of NLC film changed from isotropic to isotropic just by rotating the two single-mode patch cables without any orientation agent, electric, or magnetic devices. • Experimental results revealed that the temperature sensor based on the cascaded configuration showed an ultrahigh sensitivity of 43.13 nm/°C, which was amplified about 5 times contrast to a single Sagnac interferometer. We demonstrated an ultrasensitive fiber-optic temperature sensor based on cascaded Sagnac interferometers (CSIs). One of the Sagnac interferometers (SIs) consisted of a panda polarization-maintaining fiber (PMF) as the reference arm, while the other one contained two single-mode patch cables in a ferrule matching sleeve as the sensing arm, where a nematic liquid crystal (NLC) film was infiltrated into the micron-scale gap of the sleeve. In the sensing SI, the orientation of NLC film was induced by just rotating the two single-mode patch cables without any orientation agent, electric, or magnetic devices. Vernier effect was acquired by adjusting the thickness of NLC film. Experimental results revealed that the temperature sensitivity of the CSIs was up to 43.13 nm/°C, which was enhanced about 5 times compared to the single NLC SI. The designed optical fiber temperature sensor possessed the merits of compact structure, high stability, ultrahigh sensitivity, low hysteresis effect and high resolution, showing a promising application prospect in some scientific filed requiring accurate temperature measurement, such as biomolecules, medicine and other filed. [ABSTRACT FROM AUTHOR]

Published

2022

4. Bubble microcavity strain and gravity sensor with temperature and bending insensitivity using an ultra-thin core optical fiber.

Author

Chen, Hailiang, Zheng, Yu, Li, Baocheng, Liu, Yundong, Zhang, Yingyue, Ma, Mingjian, and Shum, Perry Ping

Subjects

*OPTICAL fiber detectors, *OPTICAL fibers, *PLASTIC optical fibers, *MICROBUBBLES, *STRAIN sensors, *TEMPERATURE sensors, *ELECTRIC arc, *FABRY-Perot interferometers

Abstract

• A bubble microcavity in an ultra-thin core optical fiber was fabricated to form a Fabry-Perot interferometer. • The size of the bubble decreased gradually with further arc discharges, which was inverse to the reported literature. • The bubble microcavity in the ultra-thin core optical fiber showed a strain sensitivity of 2.08 pm/με and a gravity sensitivity of 2.908 nm/N in a large measurement range. • The bubble microcavity in the ultra-thin core optial fiber was insensitive to temperature and bending, which was benefit to avoid the cross influences. Recent progress in optical fiber sensors based on Fabry-Perot interferometers (FPIs) has achieved much attention. In this paper, we designed and fabricated an FPI sensor by building a bubble in an ultra-thin core optical fiber. The size of the bubble decreased gradually with further arc discharges, which was inverse to the bubble fabrication in standard single mode fibers and multimode fibers. The bubble microcavity in the ultra-thin core optical fiber demonstrated a strain sensitivity of 2.08 pm/με in the range of 0–5000 με and a gravity sensitivity of 2.908 nm/N in the range of 0–4.89 N with high linear responses. Meanwhile, the bubble microcavity sensor was insensitive to temperature and bending, which was benefit to avoid the cross influences. The FPI sensor based on a bubble microcavity in an ultra-thin core optical fiber possesses the properties of easy to fabricate, small size, robustness, and high sensitivity. [ABSTRACT FROM AUTHOR]

Published

2021

5. Highly sensitive sensor based on D-shaped microstructure fiber with hollow core.

Author

Guo, Ying, Li, Jianshe, Wang, Xinyu, Zhang, Shuhuan, Liu, Yundong, Wang, Jie, Wang, Shun, Meng, Xiaojian, Hao, Rui, and Li, Shuguang

Subjects

*HOLLOW fibers, *SURFACE plasmon resonance, *PLASTIC optical fibers, *PLASMONICS, *DETECTORS, *PHOTONIC crystal fibers, *MICROSTRUCTURE

Abstract

• The D-shaped microstructure fiber sensor is suitable for external plasmonic sensing. • The fiber sensor performs sensing detection by means of double resonance peaks. • The fiber sensor has high sensitivity, high resolution and high figure of merit at the near-infrared wavelength. • Double-peaks detection is simultaneously self-calibrated as both detection and verification. A miniature D-shaped microstructure fiber sensor is proposed for external plasmonic sensing. The hollow core not only effectively modulates the core field, but also efficiently facilitates the excitation of surface plasmon resonance near the micro-opening. The refractive indices of analyte ranging from 1.37 to 1.41 can be detected by double-loss peaks tracing in the near-infrared wavelength. And the more reliable method of double-peaks detection achieves detection and verification simultaneously, which improves largely the accuracy of sensing detection. In addition, the transmission properties and sensing characteristics for the designed sensor is explored as well corresponding to various geometrical parameters. An average wavelength sensitivity is 26,927 nm/RIU with the resolution of 3.71 × 10−6 RIU, and the maximum amplitude sensitivity of 5059 RIU−1 is obtained with the resolution of 1.97 × 10−6 RIU, moreover, the maximum figure of merit can reach to 1282, which can be found a wide application prospect in the field of chemical, biological and medical. [ABSTRACT FROM AUTHOR]

Published

2020