Research Advances on Fiber-Optic SPR Sensors with Temperature Self-Compensation

Zhao, Hongxia; Wang, Rui; Han, Zhaojia; Cheng, Peihong; Ding, Zhiqun

doi:10.3390/s23020644

Cited by 11 publications

(4 citation statements)

References 90 publications

(106 reference statements)

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“…Optical-fiber-based sensors are becoming increasingly mature and in greater demand in the fields of energy, biotechnology, biomedicine, superconducting magnets, automotive technology, aerospace, healthcare, and civil engineering [ 1 , 2 , 3 , 4 , 5 , 6 ]. These sensors have been extensively researched due to their advantages, such as passive operation, ease of fabrication, compact size, resistance to corrosion, remote sensing ability, capacity for distant sensing, and resistance to electromagnetic interference [ 7 , 8 , 9 , 10 , 11 ].…”

Section: Introductionmentioning

confidence: 99%

Sequential Dual Coating with Thermosensitive Polymers for Advanced Fiber Optic Temperature Sensors

Salunkhe

Kim

2023

Sensors

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We systematically designed dual polymer Fabry–Perrot interferometer (DPFPI) sensors, which were used to achieve highly sensitive temperature sensors. The designed and fabricated DPFPI has a dual polymer coating layer consisting of thermosensitive poly (methyl methacrylate) (PMMA) and polycarbonate (PC) polymers. Four different DPFPI sensors were developed, in which different coating optical path lengths and the resultant optical properties were generated by the Vernier effect, changing the sequence of the applied polymers and varying the concentration of the coating solutions. The experimental results confirmed that the PC_PMMA_S1 DPFPI sensor delivered a temperature sensitivity of 1238.7 pm °C−1, which was approximately 4.4- and 1.4-fold higher than that of the PMMA and PMMA_PC_S1-coated sensor, respectively. Thus, the results reveal that the coating sequence, the compact thickness of the dual polymer layers, and the resultant optical parameters are accountable for achieving sensors with high sensitivity. In the PC_ PMMA-coated sensor, the PMMA outer layer has comparatively better optical properties than the PC, which might produce synergistic effects that create a large wavelength shift with small temperature deviations. Therefore, it is considered that the extensive results with the PC_PMMA_S1 DPFPI sensor validate the efficacy, repeatability, reliability, quick reaction, feasibility, and precision of the temperature readings.

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Section: Introductionmentioning

confidence: 99%

Sequential Dual Coating with Thermosensitive Polymers for Advanced Fiber Optic Temperature Sensors

Salunkhe

Kim

2023

Sensors

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“…Previous studies have demonstrated the potential of FBGs in temperature measurements, emphasizing their inherent temperature-dependent properties and high sensitivity. The development of the optical sensors based FBGs involve the fabrication process of FBGs coated with a thin layer of gold [10][11][12]. The sensors operate based on the principles of all-optical interference, utilizing the wavelength shifts of FBGs and the gold coating to accurately measure temperature variations.…”

Section: Introductionmentioning

confidence: 99%

Smart Bandages with Integrated Sensors for Real-Time Monitoring of Wound Inflammation and Infection

Kadhim,

Azzahrani,

Alsheikhy

et al. 2023

Preprint

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Developing fiber bragg grating fiber optic sensors for smart bandages offers significant advantages and has the potential to reform wound care. Smart bandages with FBG enable real-time monitoring of vital wound parameters such as temperature, moisture, and pressure and provide an accurate representation of the wound environment, allowing for immediate intervention if any wound bed complications. Therefore, integrating fiber optic sensors in smart bandages to enhance wound care and monitoring capabilities. It can be embedded directly into the bandage material, allowing for precise and localized measurements at the wound bed. This accuracy is crucial for assessing the healing progress and identifying potential issues. The suggested fiber optic sensor consists of a thin layer of gold coated onto the fiber bragg gratings. The cladding of the FBGs was etched to a thickness of 20µm to optimize the interaction with the chronic wound environment. To enhance the sensing capabilities, the sensing FBG was coated with a 50nm thick layer of gold. The system is configured to monitor changes in the reflected frequencies of the sensing FBG in response to temperature variations in the structure of the FBG in the wound bed. The response of the proposed noninvasive fiber optic sensor as a function of temperature variations within the range of 37.3 to 37.9°C is approximately 34.95 pm/°C. The sensitivity of the generated beat frequency is 4.37GHz, and the variations in the beat frequency as the temperature changes, provide valuable insights into the sensor’s response. FBG with high precision can be feasible for smart bandages and represents a significant advancement in the field of wound care. The use of these sensors supports transforming traditional bandages into intelligent and proactive healthcare solutions.

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“…Zhao et al developed a temperature self-compensating optical fiber SPR to measure temperature changes. Its application and development prospect are also expounded [ 18 ].Zhao Yong et al also studied a new type of optical fiber reflector probe to detect temperature, salinity and depth at the same time. Photonic crystal (PCF) is selected as the excitation field.…”

Section: Introductionmentioning

confidence: 99%

Temperature and salinity sensing characteristics of embedded core optical fiber based on surface plasmon resonance

Chen,

Ma,

Tian

et al. 2023

Heliyon

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Research Advances on Fiber-Optic SPR Sensors with Temperature Self-Compensation

Cited by 11 publications

References 90 publications

Sequential Dual Coating with Thermosensitive Polymers for Advanced Fiber Optic Temperature Sensors

Sequential Dual Coating with Thermosensitive Polymers for Advanced Fiber Optic Temperature Sensors

Smart Bandages with Integrated Sensors for Real-Time Monitoring of Wound Inflammation and Infection

Temperature and salinity sensing characteristics of embedded core optical fiber based on surface plasmon resonance

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