Journal of Textile Research ›› 2026, Vol. 47 ›› Issue (03): 129-138.doi: 10.13475/j.fzxb.20250900501

• Intelligent Health Monitoring Textiles • Previous Articles     Next Articles

Preparation and performance of flexible temperature sensor based on laser-induced graphene

SUN Xiaoyun, YUE Chengfei, ZHANG Ruquan()   

  1. College of Textile Science and Engineering, Wuhan Textile University, Wuhan, Hubei 430200, China
  • Received:2025-09-02 Revised:2025-12-18 Online:2026-03-15 Published:2026-03-15
  • Contact: ZHANG Ruquan E-mail:zhangruquan@wtu.edu.cn

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Abstract:

Objective This study aims to address the limitations of conventional rigid temperature sensors, such as poor flexibility, complex fabrication, and unsuitability for wearable healthcare monitoring. By utilizing laser-induced graphene (LIG) technology on polyimide (PI) substrates, a new low-cost, scalable, and flexible temperature sensor is developed. The primary goal is to enhance sensing performance, mechanical flexibility, and long-term stability, thereby enabling real-time monitoring of human physiological signals in intelligent healthcare and wearable electronics.

Method PI films were pretreated in an alkaline solution to introduce oxygen-containing functional groups to facilitate the subsequent LIG formation. Using a CO2 laser under optimized conditions for power and scanning speed, porous LIG patterns were fabricated on both PI and modified PI membranes. The prepared LIG was characterized by SEM, XPS, Raman spectroscopy, and sheet resistance tests. Finally, copper electrodes were attached with a conductive silver paste, and the device was encapsulated in polydimethylsiloxane (PDMS) to yield a flexible LIG-based temperature sensor.

Results Alkaline treatment significantly reduced PI surface roughness from 1.91 nm to 0.269 nm and enhanced hydrophilicity, facilitating more uniform LIG formation. SEM images revealed a porous 3D graphene structure with improved uniformity in modified PI-LIG. XPS and Raman analyses confirmed higher graphitization and reduced oxygen content in modified samples, with ID/IG ratio decreasing from 1.83 to 0.83. The optimal LIG exhibited a sheet resistance of 18 Ω/□ at 40% laser power and 550 mm/s scan speed. The sensor demonstrated a linear resistance-temperature relationship from 25-75 ℃, with a temperature coefficient of resistance 0.134%/℃ and excellent linearity (R2=0.997 3). It showed rapid response and recovery times, high repeatability over 10 cycles, and stable performance over 10 d. Applications included real-time monitoring of breathing patterns (slow, normal, and rapid breathing) and skin temperature at various body sites (forehead, wrist, and knee), with accurate and consistent readings matching physiological ranges.

Conclusion This research demonstrates a facile and efficient method to fabricate high-performance flexible temperature sensors using LIG technology on alkali-modified PI substrates. The developed device combines excellent linear sensitivity, fast response, repeatability, and long-term stability with low-cost, scalable manufacturing. Its proven ability to monitor both body temperature and respiratory behaviors indicates strong potential for integration into wearable electronics, smart healthcare systems, and personalized medical monitoring. In future work, sensor miniaturization, multi-signal integration, and wireless data transmission may further expand its application prospects, paving the way for advanced intelligent healthcare platforms.

Key words: laser-induced graphene, polyimide, temperature sensor, health monitoring, sensing performance, electrical conductivity, flexible sensor

CLC Number: 

  • TP 212

Fig.1

Structures and properties of PI and modified PI membranes. (a) AFM image of PI; (b) AFM image of modified PI; (c) FT-IR spectra of PI and modified PI; (d) TG curves of PI and modified PI; (e) DTG curves of PI and modified PI; (f) Stress-strain curves of PI and modified PI; (g) Water contact angles of PI and modified PI"

Fig.2

Sheet resistance variation of PI-LIG and modified PI-LIG membranes. (a) PI-LIG at low power; (b) PI-LIG at high power; (c) Modified PI-LIG"

Fig.3

SEM images of LIG. (a) PI-LIG (×3 000); (b) PI-LIG(×8 000); (c) Modified PI-LIG (×3 000); (d) Modified PI-LIG (×8 000)"

Fig.4

XPS spectra of LIG. (a) XPS full spectra; (b) C 1s spectra; (c) O 1s spectra; (d) N 1s spectra"

Fig.5

Raman spectra of LIG"

Fig.6

Sensing performance of flexible temperature sensor. (a) Resistance-temperature curve; (b) Curve of relative change rate of resistance; (c) Heating response time; (d) Cooling response time; (e) Repeatability tests at different temperatures"

Fig.7

Hysteresis and stability of flexible temperature sensors. (a) Hysteresis curve; (b) Graph showing variation of resistance over time within 10 d"

Fig.8

Respiratory monitoring experiments using flexible temperature sensor. (a) Slow breathing; (b) Normal breathing; (c) Breathalyzer test"

Fig.9

Changes of temperature and resistance rate of human skin. (a) Temperature at forehead skin; (b) Temperature at wrist area; (c) Temperature at knee area; (d) Resistance change rate at forehead skin; (e) Resistance change rate at wrist area; (f) Resistance change rate at knee area"

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