Abstract
A photothermal fiber sensor based on a microfiber knot resonator (MKR) and the Vernier effect is proposed and demonstrated. An MXene Ti3C2Tx nanosheet was deposited onto the ring of an MKR using an optical deposition method to prepare photothermal devices. An MXene MKR and a bare MKR were used as the sensing part and reference part, respectively, of a Vernier-cascade system. The optical and photothermal properties of the bare MKR and the MXene MKR were tested. Ti3C2Tx was applied to a photothermal fiber sensor for the first time. The experimental results showed that the modulation efficiency of the MXene MKR was 0.02 nm/mW, and based on the Vernier effect, the modulation efficiency of the cascade system was 0.15 nm/mW. The sensitivity was amplified 7.5 times. Our all-fiber photothermal sensor has many advantages such as low cost, small size, and good system compatibility. Our sensor has broad application prospects in many fields. The proposed stable MKR device based on two-dimensional-material modification provides a new solution for improving the sensitivity of optical fiber sensors.
Highlights
A photothermal fiber sensor based on a microfiber knot resonator (MKR) and the Vernier effect is proposed and demonstrated
Fiber optic sensors have the advantages of a large dynamic range, high sensitivity, good system compatibility, and a compact structure, and they are an attractive technology that has a wide range of application prospects in the fields of detection, medical diagnosis, and environmental monitoring [1]
We present a highly sensitive photothermal fiber sensor based on an MXene-Ti3 C2 Tx deposited MKR and bare MKR cascade
Summary
A photothermal fiber sensor based on a microfiber knot resonator (MKR) and the Vernier effect is proposed and demonstrated. An MXene MKR and a bare MKR were used as the sensing part and reference part, respectively, of a Vernier-cascade system. The experimental results showed that the modulation efficiency of the MXene MKR was 0.02 nm/mW, and based on the Vernier effect, the modulation efficiency of the cascade system was 0.15 nm/mW. The proposed stable MKR device based on two-dimensional-material modification provides a new solution for improving the sensitivity of optical fiber sensors. Fiber optic sensors have the advantages of a large dynamic range, high sensitivity, good system compatibility, and a compact structure, and they are an attractive technology that has a wide range of application prospects in the fields of detection, medical diagnosis, and environmental monitoring [1]. The structures commonly used in phase fiber sensors include interferometer and resonator structures
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