Copper-coated yarn architectures for knitted fabrics with enhanced strain sensitivity and wrist posture recognition

Wei Ke; Yixin Liang; Jinchun Liu; Yan Huang; Zhao Li; Ming Yang; Sakil Mahmud

doi:10.1007/s11706-026-0758-z

Front. Mater. Sci. ›› 2026, Vol. 20 ›› Issue (1) :260758 DOI: 10.1007/s11706-026-0758-z

RESEARCH ARTICLE

Copper-coated yarn architectures for knitted fabrics with enhanced strain sensitivity and wrist posture recognition

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Abstract

Knitted flexible sensors, owing to their looped architecture, exhibit excellent stretchability, comfort, and responsiveness, enabling real-time monitoring of biomechanical motion. Here, we systematically investigated the electromechanical performance of conductive fabrics composed of stainless steel, silver-plated, and copper-plated yarns across rib, half-air layer, and air-layer knitting structures. Among them, copper-plated rib fabrics with (35r × 35r)/5 cm density demonstrated superior sensing performance, with stable resistance variation (~2 to ~1 kΩ from 0° to 90° wrist bending), high linearity (R² = 0.959), good stability (δ = 0.232 after 100 cycles), and a gauge factor (GF) of ~2.73. An equivalent resistance model was established to elucidate the impact of loop geometry on sensor performance, confirming that higher coursewise density lowers resistance and enhances sensitivity. A wearable knitted wristband sensor was fabricated that accurately distinguishes wrist postures. These findings highlight the potential of structured conductive knits as customizable, high-performance platforms for next-generation wearable health monitoring and rehabilitation systems.

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knitted flexible sensor / electromechanical coupling / wearable health monitoring / strain-sensing fabric / conductive yarn architecture

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Wei Ke, Yixin Liang, Jinchun Liu, Yan Huang, Zhao Li, Ming Yang, Sakil Mahmud. Copper-coated yarn architectures for knitted fabrics with enhanced strain sensitivity and wrist posture recognition. Front. Mater. Sci., 2026, 20(1): 260758 DOI:10.1007/s11706-026-0758-z

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Javaid M, Haleem A, Rab S, et al. Sensors for daily life: a review.Sensors International, 2021, 2: 100121

[2]	Yin R, Wang D, Zhao S, et al. Wearable sensors-enabled human–machine interaction systems: from design to application.Advanced Functional Materials, 2021, 31(11): 2008936

[3]	Zhao J, Yang Y, Bo L, et al. Research progress on applying intelligent sensors in sports science.Sensors, 2024, 24(22): 7338

[4]	Huang X, Xue Y, Ren S, et al. Sensor-based wearable systems for monitoring human motion and posture: a review.Sensors, 2023, 23(22): 9047

[5]	Zhang Y, Xia X, Ma K, et al. Functional textiles with smart properties: their fabrications and sustainable applications.Advanced Functional Materials, 2023, 33(33): 2301607

[6]	Hossain M T, Reza S, Islam M A, et al. Progress and prospects of chemical functionalization of textiles via nanotechnology.ACS Applied Engineering Materials, 2025, 3(1): 1–20

[7]	Júnior H L O, Neves R M, Monticeli F M, et al. Smart fabric textiles: recent advances and challenges.Textiles, 2022, 2(4): 582–605

[8]	Qin J, Habib S, Shao X, et al. AI-assisted dyeing optimization of polyimide fibers via backpropagation neural networks.Progress in Organic Coatings, 2025, 209: 109611

[9]	Jegan R, Nimi W S . On the development of low power wearable devices for assessment of physiological vital parameters: a systematic review.Journal of Public Health, 2023, 32: 1–16

[10]	Cherenack K, van Pieterson L . Smart textiles: challenges and opportunities.Journal of Applied Physics, 2012, 112: 091301

[11]	Kumari A, Sengupta A, Agarwal A . The role of conducting yarns in shaping next-generation wearable sensors: a review.ACS Applied Materials & Interfaces, 2025, 17(30): 42541–42567

[12]	Liu X, Wei Y, Qiu Y . Advanced flexible skin-like pressure and strain sensors for human health monitoring.Micromachines, 2021, 12(6): 695

[13]	Islam G M N, Ali A, Collie S . Textile sensors for wearable applications: a comprehensive review.Cellulose, 2020, 27(11): 6103–6131

[14]	Choudhry N A, Arnold L, Rasheed A, et al. Textronics — a review of textile-based wearable electronics.Advanced Engineering Materials, 2021, 23(12): 2100469

[15]	Zhang J W, Zhang Y, Li Y Y, et al. Textile-based flexible pressure sensors: a review.Polymer Reviews, 2022, 62(1): 65–94

[16]	Ishac K, Suzuki K . LifeChair: a conductive fabric sensor-based smart cushion for actively shaping sitting posture.Sensors, 2018, 18(7): 2261

[17]	Jeong Y J, Kim Y E, Kim K J, et al. Multilayered fabric pressure sensor for real-time piezo-impedance imaging of pressure distribution.IEEE Transactions on Instrumentation and Measurement, 2020, 69(2): 565–572

[18]	Nan N, He J, You X, et al. A stretchable, highly sensitive, and multimodal mechanical fabric sensor based on electrospun conductive nanofiber yarn for wearable electronics.Advanced Materials Technologies, 2019, 4(3): 1800338

[19]	Lv J C, Zhang L P, Zhong Y, et al. High-performance polypyrrole coated knitted cotton fabric electrodes for wearable energy storage.Organic Electronics, 2019, 74: 59–68

[20]	Wang H, Li S, Wang Y, et al. Bioinspired fluffy fabric with in situ grown carbon nanotubes for ultrasensitive wearable airflow sensor.Advanced Materials, 2020, 32(11): 1908214

[21]	Masihi S, Atashbar M Z, Panahi M, , et al. A novel printed fabric based porous capacitive pressure sensor for flexible electronic applications. In: 2019 IEEE SENSORS, 2019, 1‒4

[22]	Zheng Y, Li Y, Zhou Y, et al. High-performance wearable strain sensor based on graphene/cotton fabric with high durability and low detection limit.ACS Applied Materials & Interfaces, 2020, 12(1): 1474–1485

[23]	Zheng Y, Yin R, Zhao Y, et al. Conductive MXene/cotton fabric based pressure sensor with both high sensitivity and wide sensing range for human motion detection and E-skin.Chemical Engineering Journal, 2021, 420: 127720

[24]	Maity D, Kumar R T R . Polyaniline anchored MWCNTs on fabric for high performance wearable ammonia sensor.ACS Sensors, 2018, 3(9): 1822–1830

[25]	Aziz S, Chang S H . Smart-fabric sensor composed of single-walled carbon nanotubes containing binary polymer composites for health monitoring.Composites Science and Technology, 2018, 163: 1–9

[26]	Wang S, Ning H M, Hu N, et al. Environmentally-friendly and multifunctional graphene-silk fabric strain sensor for human-motion detection.Advanced Materials Interfaces, 2020, 7(1): 1901507

[27]	Chun S, Son W, Kim D W, et al. Water-resistant and skin-adhesive wearable electronics using graphene fabric sensor with octopus-inspired microsuckers.ACS Applied Materials & Interfaces, 2019, 11(18): 16951–16957

[28]	Xie J, Jia Y T, Miao M H . High sensitivity knitted fabric bi-directional pressure sensor based on conductive blended yarn.Smart Materials and Structures, 2019, 28(3): 035017

[29]	Ma Z H, Xu R, Wang W, et al. A wearable, anti-bacterial strain sensor prepared by silver plated cotton/spandex blended fabric for human motion monitoring.Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2019, 582: 123918

[30]	Liu Z K, Li Z H, Zhai H, et al. A highly sensitive stretchable strain sensor based on multi-functionalized fabric for respiration monitoring and identification.Chemical Engineering Journal, 2021, 426: 130869

[31]	Cheng K B, Ueng T H, Dixon G . Electrostatic discharge properties of stainless steel/polyester woven fabrics.Textile Research Journal, 2001, 71(8): 732–738

[32]	Choi M S, Ashdown S P . Effect of changes in knit structure and density on the mechanical and hand properties of weft-knitted fabrics for outerwear.Textile Research Journal, 2000, 70(12): 1033–1045

[33]	Memon H, Hu D F, Wu L Y, et al. Structure, properties, and fabric applicability of sustainable paper yarn with high washing stability.Heliyon, 2024, 10(5): e27467

[34]	Zhang J, Li T, Liu T, et al. Preparation of an all-natural seaweed functionalized lyocell fiber: a scalable approach from nature to fabrics.Fibers and Polymers, 2024, 25(11): 4257–4269

[35]	Wang Y, Zhang P . A comparative study of polyvinylidene fluoride and polypropylene hernia meshes in creep behavior and elasticity.Textile Research Journal, 2014, 84(14): 1558–1566

[36]	Yan W J, Fuh H R, Lv Y H, et al. Giant gauge factor of Van der Waals material based strain sensors.Nature Communications, 2021, 12(1): 2018

[37]	Ou J, Xie J, Jia Y . Structural design and electrical characteristics of wearable and flexible stainless steel/polyester fibre mixture.Fibers and Polymers, 2021, 22(3): 854–861

[38]	Min J, Hu J, Sun C, et al. Fabrication processes of metal-fiber reinforced polymer hybrid components: a review.Advanced Composites and Hybrid Materials, 2022, 5(2): 651–678

[39]	Lam N Y K, Tan J, Toomey A, et al. Washability and abrasion resistance of illuminative knitted e-textiles with POFs and silver-coated conductive yarns.Fashion and Textiles, 2022, 9(1): 39

[40]	Ruppert-Stroescu M, Balasubramanian M . Effects of stitch classes on the electrical properties of conductive threads.Textile Research Journal, 2018, 88(21): 2454–2463

[41]	Liu S, Yang C, Zhao Y, et al. The impact of float stitches on the resistance of conductive knitted structures.Textile Research Journal, 2016, 86(14): 1455–1473

[42]	Hu H, Wang Z Y, Liu S . Development of auxetic fabrics using flat knitting technology.Textile Research Journal, 2011, 81(14): 1493–1502

[43]	Atalay O, Kennon W R, Demirok E . Weft-knitted strain sensor for monitoring respiratory rate and its electro-mechanical modeling.IEEE Sensors Journal, 2015, 15(1): 110–122

[44]	Arruda L M, Moreira I P, Sanivada U K, et al. Development of piezoresistive sensors based on graphene nanoplatelets screen-printed on woven and knitted fabrics: optimisation of active layer formulation and transversal/longitudinal textile direction.Materials, 2022, 15(15): 5185

[45]	Seyedin S, Moradi S, Singh C, et al. Continuous production of stretchable conductive multifilaments in kilometer scale enables facile knitting of wearable strain sensing textiles.Applied Materials Today, 2018, 11: 255–263

[46]	Li S, Liu G D, Li R, et al. Contact-resistance-free stretchable strain sensors with high repeatability and linearity.ACS Nano, 2022, 16(1): 541–553

[47]	Liu S. A study of the influence of different structures on resistivity of conductive knitted fabrics. Dissertation for the Doctoral Degree. Hong Kong: The Hong Kong Polytechnic University, 2017