Micromesh reinforced strain sensor with high stretchability and stability for full-range and periodic human motions monitoring

Haidong Liu; Chang Liu; Jinan Luo; Hao Tang; Yuanfang Li; Houfang Liu; Jingzhi Wu; Fei Han; Zhiyuan Liu; Jianhe Guo; Rongwei Tan; Tian-Ling Ren; Yancong Qiao; Jianhua Zhou

doi:10.1002/inf2.12511

InfoMat ›› 2024, Vol. 6 ›› Issue (4) : e12511. DOI: 10.1002/inf2.12511

RESEARCH ARTICLE

Micromesh reinforced strain sensor with high stretchability and stability for full-range and periodic human motions monitoring

Haidong Liu¹^,² ,
Chang Liu¹^,² ,
Jinan Luo¹^,² ,
Hao Tang¹^,² ,
Yuanfang Li¹^,² ,
Houfang Liu³ ,
Jingzhi Wu¹^,² ,
Fei Han⁴ ,
Zhiyuan Liu⁴ ,
Jianhe Guo¹^,² ,
Rongwei Tan⁵ ,
Tian-Ling Ren³ ,
Yancong Qiao¹^,² ,
Jianhua Zhou¹^,²

Author information +

History +

Abstract

The development of strain sensors with high stretchability and stability is an inevitable requirement for achieving full-range and long-term use of wearable electronic devices. Herein, a resistive micromesh reinforced strain sensor (MRSS) with high stretchability and stability is prepared, consisting of a laser-scribed graphene (LSG) layer and two styrene-block-poly(ethylene-ran-butylene)-block-poly-styrene micromesh layers embedded in Ecoflex. The micromesh reinforced structure endows the MRSS with combined characteristics of a high stretchability (120%), excellent stability (with a repetition error of 0.8% after 11 000 cycles), and outstanding sensitivity (gauge factor up to 2692 beyond 100%). Impressively, the MRSS can still be used continauously within the working range without damage, even if stretched to 300%. Furthermore, compared with different structure sensors, the mechanism of the MRSS with high stretchability and stability is elucidated. What's more, a multilayer finite element model, based on the layered structure of the LSG and the morphology of the cracks, is proposed to investigate the strain sensing behavior and failure mechanism of the MRSS. Finally, due to the outstanding performance, the MRSS not only performes well in monitoring full-range human motions, but also achieves intelligent recognitions of various respiratory activities and gestures assisted by neural network algorithms (the accuracy up to 94.29% and 100%, respectively). This work provides a new approach for designing high-performance resistive strain sensors and shows great potential in full-range and long-term intelligent health management and human–machine interactions applications.

Keywords

flexible strain sensor / excellent stretchability and stability / layered laser-scribed graphene / micromesh reinforced structure / multilayer finite element model

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

Haidong Liu, Chang Liu, Jinan Luo, Hao Tang, Yuanfang Li, Houfang Liu, Jingzhi Wu, Fei Han, Zhiyuan Liu, Jianhe Guo, Rongwei Tan, Tian-Ling Ren, Yancong Qiao, Jianhua Zhou. Micromesh reinforced strain sensor with high stretchability and stability for full-range and periodic human motions monitoring. InfoMat, 2024, 6(4): e12511 https://doi.org/10.1002/inf2.12511

References

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

[1]	Amjadi M, Kyung KU, Park I, Sitti M. Stretchable, skin-mountable, and wearable strain sensors and their potential applications: a review. Adv Funct Mater. 2016;26(11):1678-1698.

[2]	Trung TQ, Lee NE. Flexible and stretchable physical sensor integrated platforms for wearable human-activity monitoring and personal healthcare. Adv Mater. 2016;28(22):4338-4372.

[3]	Seyedin S, Zhang P, Naebe M, et al. Textile strain sensors: a review of the fabrication technologies, performance evaluation and applications. Mater Horizons. 2019;6(2):219-249.

[4]	Liu XH, Miao JL, Fan Q, et al. Recent progress on smart fiber and textile based wearable strain sensors: materials, fabrications and applications. Adv Fiber Mater. 2022;4(3):361-389.

[5]	Park C, Kim MS, Kim HH, et al. Stretchable conductive nanocomposites and their applications in wearable devices. Appl Phys Rev. 2022;9(2):021312.

[6]	Souri H, Banerjee H, Jusufi A, et al. Wearable and stretchable strain sensors: materials, sensing mechanisms, and applications. Adv Intell Syst. 2020;2(8):2000039.

[7]	Huang YX, Tao LQ, Yu JB, Wang Z, Zhu C, Chen X. Integrated sensing and warning multifunctional devices based on the combined mechanical and thermal effect of porous graphene. ACS Appl Mater Interfaces. 2020;12(47):53049-53057.

[8]	Li YX, He TY, Shi LJ, Wang RR, Sun J. Strain sensor with both a wide sensing range and high sensitivity based on braided graphene belts. ACS Appl Mater Interfaces. 2020;12(15):17691-17698.

[9]	Kim D, Chhetry A, Abu Zahed M, et al. Highly sensitive and reliable piezoresistive strain sensor based on cobalt nanoporous carbon-incorporated laser-induced graphene for smart healthcare wearables. ACS Appl Mater Interfaces. 2023;15(1):1475-1485.

[10]	Liu W, Chen Q, Huang YH, Wang D, Li L, Liu Z. In situ laser synthesis of Pt nanoparticles embedded in graphene films for wearable strain sensors with ultra-high sensitivity and stability. Carbon. 2022;190:245-254.

[11]	Yang Z, Wang DY, Pang Y, et al. Simultaneously detecting subtle and intensive human motions based on a silver nanoparticles bridged graphene strain sensor. ACS Appl Mater Interfaces. 2018;10(4):3948-3954.

[12]	Chhetry A, Sharifuzzaman M, Yoon H, Sharma S, Xuan X, Park JY. MoS₂-decorated laser-induced graphene for a highly sensitive, hysteresis-free, and reliable piezoresistive strain sensor. ACS Appl Mater Interfaces. 2019;11(25):22531-22542.

[13]	Wang WT, Lu LS, Li ZH, et al. Fingerprint-inspired strain sensor with balanced sensitivity and strain range using laser-induced graphene. ACS Appl Mater Interfaces. 2022;14(1):1315-1325.

[14]	Wang JX, Liu LP, Yang C, et al. Ultrasensitive, highly stable, and flexible strain sensor inspired by nature. ACS Appl Mater Interfaces. 2022;14(14):16885-16893.

[15]	Cheng Y, Wang RR, Sun J, Gao L. A stretchable and highly sensitive graphene-based fiber for sensing tensile strain, bending, and torsion. Adv Mater. 2015;27(45):7365-7371.

[16]	Yang YN, Cao ZR, He P, et al. Ti₃C₂T_x MXene-graphene composite films for wearable strain sensors featured with high sensitivity and large range of linear response. Nano Energy. 2019;66:104134.

[17]	Yang YN, Shi LJ, Cao ZR, Wang RR, Sun J. Strain sensors with a high sensitivity and a wide sensing range based on a Ti₃C₂T_x (MXene) nanoparticle-nanosheet hybrid network. Adv Funct Mater. 2019;29(14):1807882.

[18]	Zhang Q, Liu X, Duan LJ, Gao GH. Ultra-stretchable wearable strain sensors based on skin-inspired adhesive, tough and conductive hydrogels. Chem Eng J. 2019;365:10-19.

[19]	Cheng BW, Li YX, Li H, et al. An adhesive and self-healable hydrogel with high stretchability and compressibility for human motion detection. Compos Sci Technol. 2021;213:108948.

[20]	Wang YL, Hao J, Huang ZQ, et al. Flexible electrically resistive-type strain sensors based on reduced graphene oxide-decorated electrospun polymer fibrous mats for human motion monitoring. Carbon. 2018;126:360-371.

[21]	Gao JF, Li B, Huang XW, et al. Electrically conductive and fluorine free superhydrophobic strain sensors based on SiO₂/graphene-decorated electrospun nanofibers for human motion monitoring. Chem Eng J. 2019;373:298-306.

[22]	Dong JC, Li L, Zhang C, et al. Ultra-highly stretchable and anisotropic SEBS/F127 fiber films equipped with an adaptive deformable carbon nanotube layer for dual-mode strain sensing. J Mater Chem A. 2021;9(34):18294-18305.

[23]	Wang QQ, Zeng J, Li J, et al. Multifunctional fiber derived from wet spinning combined with UV photopolymerization for human motion and temperature detection. Adv Compos Hybrid Mater. 2023;6(1):26.

[24]	Hu YF, Huang TQ, Zhang HJ, et al. Ultrasensitive and wearable carbon hybrid fiber devices as robust intelligent sensors. ACS Appl Mater Interfaces. 2021;13(20):23905-23914.

[25]	Tao LQ, Wang DY, Tian H, et al. Self-adapted and tunable graphene strain sensors for detecting both subtle and large human motions. Nanoscale. 2017;9(24):8266-8273.

[26]	Gao ZY, Xiao X, Carlo AD, et al. Advances in wearable strain sensors based on electrospun fibers. Adv Funct Mater. 2023;33(18):2214265.

[27]	Li J, Wang LJ, Wang XZ, et al. Highly conductive PVA/Ag coating by aqueous in situ, reduction and its stretchable structure for strain sensor. ACS Appl Mater Interfaces. 2020;12(1):1427-1435.

[28]	Yang ST, Li CW, Chen XY, et al. Facile fabrication of high-performance pen ink-decorated textile strain sensors for human motion detection. ACS Appl Mater Interfaces. 2020;12(17):19874-19881.

[29]	Luo CS, Tian B, Liu Q, Feng Y, Wu W. One-step-printed, highly sensitive, textile-based, tunable performance strain sensors for human motion detection. Adv Mater Technol. 2020;5(2):1900925.

[30]	Wang ZF, Huang Y, Sun JF, et al. Polyurethane/cotton/carbon nanotubes core-spun yarn as high reliability stretchable strain sensor for human motion detection. ACS Appl Mater Interfaces. 2016;8(37):24837-24843.

[31]	Chao MY, Wang YG, Ma D, et al. Wearable MXene nanocomposites-based strain sensor with tile-like stacked hierarchical microstructure for broad-range ultrasensitive sensing. Nano Energy. 2020;78:105187.

[32]	Tian H, Yang Y, Xie D, et al. Wafer-scale integration of graphene-based electronic, optoelectronic and electroacoustic devices. Sci Rep. 2014;4(1):3598.

[33]	Rahmani P, Shojaei A. A review on the features, performance and potential applications of hydrogel-based wearable strain/pressure sensors. Adv Colloid Interface Sci. 2021;298:102553.

[34]	Fu YF, Li YQ, Liu YF, Huang P, Hu N, Fu SY. High-performance structural flexible strain sensors based on graphene-coated glass fabric/silicone composite. ACS Appl Mater Interfaces. 2018;10(41):35503-35509.

[35]	Chhetry A, Sharma S, Barman SC, et al. Black phosphorus@laser-engraved graphene heterostructure-based temperature-strain hybridized sensor for electronic-skin applications. Adv Funct Mater. 2021;31(10):2007661.

[36]	Li QS, Wu TY, Zhao W, Ji JW, Wang G. Laser-induced corrugated graphene films for integrated multimodal sensors. ACS Appl Mater Interfaces. 2021;13(31):37433-37444.

[37]	Raza T, Tufail MK, Ali A, et al. Wearable and flexible multifunctional sensor based on laser-induced graphene for the sports monitoring system. ACS Appl Mater Interfaces. 2022;14(48):54170-54181.

[38]	Wang H, Zhao ZF, Liu PP, Pan Y, Guo XG. Stretchable sensors and electro-thermal actuators with self-sensing capability using the laser-induced graphene technology. ACS Appl Mater Interfaces. 2022;14(36):41283-41295.

[39]	Zhai KK, Wang H, Ding QL, et al. High-performance strain sensors based on organohydrogel microsphere film for wearable human–computer interfacing. Adv Sci. 2023;10(6):2205632.

[40]	Jeong H, Lee JY, Lee K, et al. Differential cardiopulmonary monitoring system for artifact-canceled physiological tracking of athletes, workers, and COVID-19 patients. Sci Adv. 2021;7(20):eabg3092.

[41]	Ye ZL, Ling Y, Yang MY, et al. A breathable, reusable, and zero-power smart face mask for wireless cough and mask-wearing monitoring. ACS Nano. 2022;16(4):5874-5884.

[42]	Ni XY, Ouyang W, Jeong H, et al. Automated, multiparametric monitoring of respiratory biomarkers and vital signs in clinical and home settings for COVID-19 patients. Proc Natl Acad Sci U S A. 2021;118(19):e2026610118.

[43]	Chen SC, Qian GC, Ghanem B, et al. Quantitative and real-time evaluation of human respiration signals with a shape-conformal wireless sensing system. Adv Sci. 2022;9(32):2203460.

[44]	Suo J, Liu YF, Wu C, et al. Wide-bandwidth nanocomposite-sensor integrated smart mask for tracking multiphase respiratory activities. Adv Sci. 2022;9(31):2203565.