[1] [1] 张森浩， 邱东海， 衣宁， 等. 可穿戴柔性电子的快速制备与医疗应用［J］. 光学 精密工程， 2019， 27（6）： 1362-1369. doi: 10.3788/ope.20192706.1362ZHANGS H， QIUD H， YIN， et al. Rapid preparation and medical application of wearable Flexible electronics［J］. Opt. Precision Eng.， 2019， 27（6）： 1362-1369.（in Chinese）. doi: 10.3788/ope.20192706.1362

[2] H M WANG, S LI, H J LU et al. Carbon-based flexible devices for comprehensive health monitoring. Small Methods, 7, 2201340(2023).

[3] C ZHU, J W WU, J H YAN et al. Advanced fiber materials for wearable electronics. Advanced Fiber Materials, 5, 12-35(2023).

[4] J Z SUN, R SUN, P JIA et al. Fabricating flexible conductive structures by printing techniques and printable conductive materials. Journal of Materials Chemistry C, 10, 9441-9464(2022).

[5] W D YANG, X CHENG, Z H GUO et al. Design， fabrication and applications of flexible RFID antennas based on printed electronic materials and technologies. Journal of Materials Chemistry C, 11, 406-425(2023).

[6] S ZHANG, L WANG, Y LUO et al. A convenient， low-cost graphene UV-cured additive manufacturing electronic process to achieve flexible sensors. Chemical Engineering Journal, 451, 138521(2023).

[7] HS JEON, W YAO, KH KIM et al. Stable， amphiphobic， and electrically conductive coating on flexible polyimide substrate. Journal of Industrial and Engineering Chemistry, 120, 429-438(2023).

[8] [8] 郑高峰， 姜佳昕， 康国毅， 等. 光栅编码器电纺直写精确喷印［J］. 光学 精密工程， 2021， 29（10）： 2393-2399. doi: 10.37188/ope.2021.0092ZHENGG F， JIANGJ X， KANGG Y， et al. Optical grating encoder via precise electrohydrodynamic direct-writing［J］. Opt. Precision Eng.， 2021， 29（10）： 2393-2399.（in Chinese）. doi: 10.37188/ope.2021.0092

[9] X M LIU, J L TONG, J J WANG et al. BaTiO₃/MXene/PVDF-TrFE composite films via an electrospinning method for flexible piezoelectric pressure sensors. Journal of Materials Chemistry C, 11, 4614-4622(2023).

[10] [10] 赵扬， 姜佳昕， 张恺， 等. 基于电纺直写的图案化微纳结构喷印技术［J］. 光学 精密工程， 2016， 24（9）： 2224-2231. doi: 10.3788/ope.20162409.2224ZHAOY， JIANGJ X， ZHANGK， et al. Precision deposition of micro/nano pattern printed by electrohydrodynamic direct-write［J］. Opt. Precision Eng.， 2016， 24（9）： 2224-2231.（in Chinese）. doi: 10.3788/ope.20162409.2224

[11] J XU, Y CHEN, W ZHANG et al. Direct ink writing of nAl/pCuO/HPMC with outstanding combustion performance and ignition performance. Combustion and Flame, 236, 111747(2022).

[12] B KSAPABUTR, M PANAPOY. Fundamentals of Electrospinning and Safety. Metal Oxide-Based Nanofibers and Their Applications, 3-30(2022).

[13] F NIKBAKHTNASRABADI, E S HOSSEINI, S DERVIN et al. Smart bandage with inductor-capacitor resonant tank based printed wireless pressure sensor on electrospun poly-L-lactide nanofibers. Advanced Electronic Materials, 8, 2101348(2022).

[14] [14] 肖渊， 李倩， 张威， 等. 微喷印原电池置换成型织物基柔性导电线路的影响因素研究［J］. 纺织学报， 2022， 43（10）89-96XIAOY， LIQ， ZHANGW， et al. Influencing factors on flexible fabric-based electrical circuit formation by micro-jet printed primary cell replacement deposition［J］. Journal of Textile Research， 2022， 43（10）89-96（in Chinese）

[15] S P DOUGLAS, S MRIG, C E KNAPP. MODs vs. NPs： vying for the future of printed electronics. Chemistry （Weinheim an Der Bergstrasse， Germany）, 27, 8062-8081(2021).

[16] K S BHAT, R AHMAD, Y S WANG et al. Low-temperature sintering of highly conductive silver ink for flexible electronics. Journal of Materials Chemistry C, 4, 8522-8527(2016).

[17] B F Y REZAGA, M DONNABELLE L BALELA. Chemical sintering of Ag nanoparticle conductive inks at room temperature for printable electronics. Journal of Materials Science： Materials in Electronics, 32, 17764-17779(2021).

[18] J HE, X ZHENG, Z ZHENG et al. Pair directed silver nano-lines by single-particle assembly in nanofibers for non-contact humidity sensors. Nano Energy, 92, 106748(2022).

[19] N LIU, X SUN, Z CHEN et al. Direct ink writing of dense alumina ceramics prepared by rapid sintering. Ceramics International, 48, 30767-30778(2022).

[20] A R DIXIT. Direct ink writing of carbon-doped polymeric composite ink： a review on its requirements and applications. 3D Printing and Additive Manufacturing, 10, 828-854(2023).

[21] SB AZIZ, RB MARIF, MA BRZA et al. Structural， thermal， morphological and optical properties of PEO filled with biosynthesized Ag nanoparticles： new insights to band gap study. Results in Physics, 13, 102220(2019).

[22] Z ZHANG, H HE, W FU et al. Electro-hydrodynamic direct-writing technology toward patterned ultra-thin fibers： advances， materials and applications. Nano Today, 35, 100942(2020).

[23] M M NAZEMI, A KHODABANDEH, A HADJIZADEH. Near-field electrospinning： crucial parameters， challenges， and applications. ACS Applied Bio Materials, 5, 394-412(2022).

[24] G S BISHT, G CANTON, A MIRSEPASSI et al. Controlled continuous patterning of polymeric nanofibers on three-dimensional substrates using low-voltage near-field electrospinning. Nano Letters, 11, 1831-1837(2011).

[25] [25] 李文望， 郑高峰， 王翔， 等. 电纺直写纳米纤维在图案化基底的定位沉积［J］. 光学 精密工程， 2010， 18（10）2231-2238. doi: 10.3788/OPE.20101810.2231LIW W， ZHENGG F， WANGX， et al. Position deposition of electrospinning direct-writing nanofiber on pattern substrate［J］. Opt. Precision Eng.， 2010， 18（10）2231-2238（in Chinese）. doi: 10.3788/OPE.20101810.2231

[26] J FANG, H X WANG, H T NIU et al. Evolution of fiber morphology during electrospinning. Journal of Applied Polymer Science, 118, 2553-2561(2010).

[27] A MOHAN, R SINGHAL, S R RAMANAN. A study on the effect of the collector properties on the fabrication of magnetic polystyrene nanocomposite fibers using the electrospinning technique. Journal of Applied Polymer Science, 140, 643-650(2023).

[28] Y MOU, H WANG, Y PENG et al. Low temperature enhanced flexible conductive film by Ag flake/ion composite ink. Materials & Design, 186, 108339(2020).

[29] Y S PARK, J KIM, J M OH et al. Near-field electrospinning for three-dimensional stacked nanoarchitectures with high aspect ratios. Nano Letters, 20, 441-448(2020).

[30] G C PIDCOCK, HET PANHUIS MIN. Extrusion printing conducting gel-carbon nanotube structures upon flexible substrates, 179-180(12).

[31] J ZHANG, Y ZHEN, H XUE et al. An urchin-like SnO₂/NaNbO₃ nanocomposite with stable humidity-sensing properties at room temperature. Sensors and Actuators B： Chemical, 283, 643-650(2019).