[1] V Annapureddy, H Palneedi, G T Hwang et al. Magnetic energy harvesting with magnetoelectrics: an emerging technology for self-powered autonomous systems. Sustainable Energy & Fuels, 1, 2039-2052(2017).

[2] J Bae, M K Song, Y J Park et al. Fiber supercapacitors made of nanowire-fiber hybrid structures for wearable/flexible energy storage. Angewandte Chemie International Edition, 50, 1683-1687(2011).

[3] M M Liu, X Pu, C Y Jiang et al. Large-area all-textile pressure sensors for monitoring human motion and physiological signals. Advanced Materials, 29, 1703700(2017).

[4] X Q Liao, Q L Liao, Z Zhang et al. A highly stretchable ZnO@Fiber-based multifunctional nanosensor for strain/temperature/UV detection. Advanced Functional Materials, 26, 3074-3081(2016).

[5] Y Pang, J M Jian, T Tu et al. Wearable humidity sensor based on porous graphene network for respiration monitoring. Biosensors and Bioelectronics, 116, 123-129(2018).

[6] A Balilonda, Q Li, X H Bian et al. Lead-free and electron transport layer-free perovskite yarns: Designed for knitted solar fabrics. Chemical Engineering Journal, 410, 128384(2021).

[7] Y J Su, C X Chen, H Pan et al. Muscle fibers inspired high-performance piezoelectric textiles for wearable physiological monitoring. Advanced Functional Materials, 31, 2010962(2021).

[8] A Fakharuddin, H Z Li, F Di Giacomo et al. Fiber-shaped electronic devices. Advanced Energy Materials, 11, 2101443(2021).

[9] Zhouping YIN, Yongan HUANG. Flexible electronics manufacturing: materials, fevices, and processes(2016).

[10] S de Mulatier, M Nasreldin, R Delattre et al. Electronic circuits integration in textiles for data processing in wearable technologies. Advanced Materials Technologies, 3, 1700320(2018).

[11] G Acar, O Ozturk, A J Golparvar et al. Wearable and flexible textile electrodes for biopotential signal monitoring: a review. Electronics, 8, 479(2019).

[12] X Q Liao, W S Wang, L Wang et al. Controllably enhancing stretchability of highly sensitive fiber-based strain sensors for intelligent monitoring. ACS Applied Materials & Interfaces, 11, 2431-2440(2019).

[13] J G Qu, N F He, S V Patil et al. Screen printing of graphene oxide patterns onto viscose nonwovens with tunable penetration depth and electrical conductivity. ACS Applied Materials & Interfaces, 11, 14944-14951(2019).

[14] K Dong, X Peng, Z L Wang. Fiber/fabric-based piezoelectric and triboelectric nanogenerators for flexible/stretchable and wearable electronics and artificial intelligence. Advanced Materials, 32, 1902549(2020).

[15] H Qin, J Li, B He et al. Novel wearable electrodes based on conductive chitosan fabrics and their application in smart garments. Materials (Basel), 11, 370(2018).

[16] Z Yang, Y Pang, X L Han et al. Graphene textile strain sensor with negative resistance variation for human motion detection. ACS Nano, 12, 9134-9141(2018).

[17] J D Shi, S Liu, L S Zhang et al. Smart textile-integrated microelectronic systems for wearable applications. Advanced Materials, 32, 1901958(2020).

[18] M Kaltenbrunner, T Sekitani, J Reeder et al. An ultra-lightweight design for imperceptible plastic electronics. Nature, 499, 458-463(2013).

[19] Q H Gao, J T Hu, Y Yang et al. Fabrication of new high-performance UHMWPE-based conductive fibers in a universal process. Industrial & Engineering Chemistry Research, 58, 935-943(2019).

[20] Z L Jiang, X Dai, H Middleton. Effect of silicon on corrosion resistance of Ti-Si alloys. Materials Science and Engineering: B, 176, 79-86(2011).

[21] M J Zhang, M L Wang, M X Zhang et al. Stretchable conductive Ni@Fe3O4@Polyester fabric strain sensor with negative resistance variation and electromagnetic interference shielding. Organic Electronics, 81, 105677(2020).

[22] M L Wang, Q H Gao, M J Zhang et al. In-situ formation of durable akaganeite (β-FeOOH) nanorods on sulfonate-modified poly(ethylene terephthalate) fabric for dual-functional wastewater treatment. Journal of Hazardous Materials, 386, 121647(2020).

[23] J J Ma, K Wang, M S Zhan. Growth mechanism and electrical and magnetic properties of Ag-Fe3O4 core-shell nanowires. ACS Applied Materials & Interfaces, 7, 16027-16039(2015).

[24] L Li, W Kang, F Li et al. Coaxial solution blowing of modified hollow polyacrylonitrile (PAN) nanofiber Fe complex (Fe-AO-CSB-HPAN) as a heterogeneous Fenton photocatalyst for organic dye degradation. RSC Advances, 5, 68439-68445(2015).

[25] Guoshi CUI, Hongying ZHAO, Xinyuan SHEN. Control of morphology and size of nano-silver particles in the liquid irradiation reduction process. Journal of Radiation Research and Radiation Processing, 28, 29-36(2010).

[26] Z Z Han, L L Ren, Z H Cui et al. Ag/ZnO flower heterostructures as a visible-light driven photocatalyst via surface plasmon resonance. Applied Catalysis B: Environmental, 126, 298-305(2012).

[27] V K Kaushik. XPS core level spectra and Auger parameters for some silver compounds. Journal of Electron Spectroscopy and Related Phenomena, 56, 273-277(1991).

[28] M J Zhang, M L Wang, M X Zhang et al. Fe3O4 nanowire arrays on flexible polypropylene substrates for UV and magnetic sensing. ACS Applied Nano Materials, 1, 5742-5752(2018).

[29] J B Mu, B Chen, Z C Guo et al. Highly dispersed Fe3O4 nanosheets on one-dimensional carbon nanofibers: synthesis, formation mechanism, and electrochemical performance as supercapacitor electrode materials. Nanoscale, 3, 5034-5040(2011).

[30] Y Farraj, M Layani, A Yaverboim et al. Binuclear copper complex ink as a seed for electroless copper plating yielding >70% bulk conductivity on 3D printed polymers. Advanced Materials Interfaces, 5, 1701285(2018).

[31] T Wang, D Wu, Y Wang et al. One-step solvothermal fabrication of Cu@PANI core-shell nanospheres for hydrogen evolution. Nanoscale, 10, 22055-22064(2018).

[32] D Jiang, Q Liu, K Wang et al. Enhanced non-enzymatic glucose sensing based on copper nanoparticles decorated nitrogen-doped graphene. Biosensors and Bioelectronics, 54, 273-278(2014).