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基于导电纤维的柔性电子器件研究进展

张文枭 左杏薇 曲丽君 张学记 苗锦雷

张文枭, 左杏薇, 曲丽君, 等. 基于导电纤维的柔性电子器件研究进展[J]. 复合材料学报, 2022, 40(0): 1-22
引用本文: 张文枭, 左杏薇, 曲丽君, 等. 基于导电纤维的柔性电子器件研究进展[J]. 复合材料学报, 2022, 40(0): 1-22
Wenxiao ZHANG, Xingwei ZUO, Lijun QU, Xueji ZHANG, Jinglei MIAO. Research progress of flexible electronic devices based on conductive fibers[J]. Acta Materiae Compositae Sinica.
Citation: Wenxiao ZHANG, Xingwei ZUO, Lijun QU, Xueji ZHANG, Jinglei MIAO. Research progress of flexible electronic devices based on conductive fibers[J]. Acta Materiae Compositae Sinica.

基于导电纤维的柔性电子器件研究进展

基金项目: 山东省自然科学基金(ZR2020 QE081);山东省重点研发计划(重大科技创新项目)(2019 JZZY010340, 2019 JZZY010335, 2019 GGX102022);中国博士后科学基金(2020 M671994)
详细信息
    通讯作者:

    曲丽君,博士,教授,博士生导师,研究方向为柔性智能可穿戴电子器件的集成应用以及石墨烯在纤维纺织品中的应用及产业化研 E-mail: lijunqu@qdu.edu.cn

    苗锦雷,博士,讲师,研究生导师,研究方向为石墨烯在纤维织物中的应用及产业化 E-mail:jinlei.miao@qdu.edu.cn

  • 中图分类号: TB333

Research progress of flexible electronic devices based on conductive fibers

Funds: Natural Science Foundation of Shandong Province of China (ZR2020 QE081);Shandong Prov ince Key Research and Development Plan (Major scientifc and technological innovation projects) (2019 JZZY010340;2019 JZZY010335;2019 GGX102022);China Postdoctoral Science Foundation(2020 M671994)
  • 摘要: 柔性电子器件具有优异的灵活性,实现了与服装的无缝集成,在各种实际的可穿戴应用中具有巨大的潜力。一维纤维状电子器件由于其优异的柔韧性、可编织性及舒适性成为智能可穿戴领域的研究热点。首先,综述了用于纤维状柔性电子器件的一维可拉伸电极的研究进展,然后详细介绍了高性能一维纤维状柔性电子器件制备过程中具有代表性的导电材料、制造技术,以及一维柔性纤维进一步应用为各类电子器件的主要制备方法,另外总结了近年来基于柔性纤维状电子器件在智能可穿戴领域的应用。最后我们对一维纤维基智能可穿戴电子器件的机遇和挑战进行了批判性思考。

     

  • 图  1  (a)石墨烯气凝胶纤维和石墨烯/相变材料(PCM)智能纤维的工艺示意图。(b)气凝胶导向智能纤维照片。(c)不同应变下的加卸载曲线,CNTs/PU螺旋纱在900%拉伸下仍具有良好的回收性能。(d)发光二极管(LED)灯显示螺旋CNTs/PU纱在拉伸过程中具有良好的导电性。(e)应用CNTs/PU螺旋纱作为应变传感器,监测行走过程中的电阻变化。它们对各种人体运动表现出快速的信号响应和稳定的电阻重复性。

    Figure  1.  (a) Process schematics of graphene aerogel fibers and graphene/PCM smart fibers. (b) Photo of aerogel-guided smart fibers. (c) Loading and unloading curves under different strains, the CNTs/PU helical yarn still has good recovery performance under 900% stretching. (d) LED light shows that the helical CNTs/PU yarn has good electrical conductivity during the stretching process. (e) Application of CNTs/PU helical yarns as strain sensors to monitor resistance changes during walking. They exhibit fast signal responses and stable resistance repeatability to various human motions.

    图  2  (a,b)超整合的镓-铟共晶合金(Ni-EGaIn)电子纹身多功能应用,两个LED阵列Ni-EGaIn电子纹身的例子。(c)将Ni-EGaIn电子纹身印在志愿者皮肤的几个身体部位:手臂、手腕、手掌、手指、膝盖和背部。(d)在电路中使用包覆纱-银纳米线-聚二甲基硅氧烷(DCY-AgNW-PDMS)的透明、可弯曲和可拉伸的LED阵列。循环弯曲试验中,光强没有明显减弱。(e)LED阵列在拉伸到30%时仍能正常工作。

    Figure  2.  (a,b) Hyperintegrated Ni-EGaIn electronic tattoo multifunctional application, two LED array Ni-EGaIn electronic tattoo examples. (c) Ni-EGaIn electronic tattoos were printed on the volunteers' skin on several body parts: arms, wrists, palms, fingers, knees, and back. (d) Transparent, bendable and stretchable LED array using DCY-AgNW-PDMS in circuit. In the cyclic bending test, the light intensity did not decrease significantly. (e) The LED array still works fine when stretched to 30%.

    图  3  (a)包芯螺旋纱(CSYs)的制备。(b)浸涂及其毛细管效应现象。(c)石墨烯基包芯螺旋纱(GCSY)作为可穿戴传感器的潜在应用前景。(d)基于PU/棉/CNTs的可拉伸导电纤维的浸涂与制造示意图。 (e)PU/棉/CNTs基导电纤维应用示意图。 (f)复合材料纤维的制造工艺示意图。双层包芯纱(DCYs)的结构表征和SEM图像。比例尺:500μm。 (g)氢气(H2)等离子体处理前后AgNWs的质量分数和DCY/AgNWs的电导率随AgNWs的浸涂覆时间的变化。(h)减少金基可拉伸导电纤维裂缝的长度和宽度的原理,在拉伸时提供了低电阻变化。(i)在PDMS薄膜上的金薄膜与制备导电纤维的照片。(j)纤维和薄膜的拉伸性和电阻变化。(k)三维螺旋纤维的制作工艺。(l)螺旋纤维型互连器的制造过程的示意图。

    Figure  3.  (a) Preparation of core-spun helix yarn (CSYs). (b) Dip coating and its capillary effect. (c) Potential applications of graphene-based core-spun yarn (GCSY) as wearable sensors. (d) Schematic diagram of dip coating and fabrication of stretchable conductive fibers based on PU/cotton /CNTs. (e) Schematic diagram of application of PU/ cotton/CNTs-based conductive fibers. (f) Schematic diagram of composite fiber manufacturing process. Structure characterization and SEM image of DCYs. Scale: 500μm. (g) Changes of AgNWs mass fraction and DCY/AgNWs conductivity with AgNWs dip coating time before and after hydrogen (H2) plasma treatment. (h) The principle of reducing the length and width of cracks in gold base stretchable conductive fibers provides low resistance changes during stretching. (i) Photographs of gold film on PDMS film and preparation of conductive fibers. (j) Changes in tensile properties and electrical resistance of fibers and films. (k) Fabrication process of three-dimensional spiral fiber. (l) Schematic diagram of the manufacturing process of spiral fiber type interconnect.

    图  4  (a)CNTs的扫描电镜图。(b)原始CNTs纱线。(c)挤压凝固浴PH值为9的MXene凝胶(MG9)的光学图像。(d)挤压MG9内部结构的SEM图像。(e) MXene含量为1的纤维、MXene含量为2的纤维和MXene含量为3的纤维的不同拉伸强度−应变曲线和(f)电导率。(g)MXene/PU纤维纺丝工艺示意图。(h)使用异丙醇(IPA)凝固浴纺丝的数码照片。(i)MXene/PU纤维不同阶段应力应变曲线示意图。(j)代表纤维的应力-应变曲线。(k)多尺度无序多孔弹性纤维制备示意图。(l)可拉伸导电纤维的热拉伸方法示意图。(m)可拉伸导电纤维的电学特性。

    Figure  4.  (a) SEM image of carbon nanotube.(b)Pristine carbon nanotube yarns. (c) Optical image of extruded MG9 (d) SEM image of the internal structure of extruded MG9. (e) Tensile strength-strain curves and (f) electrical conductivity of MF-1, MF-2 and MF-3.(g) Schematic diagram of the spinning process of MXene/PU fibers. (h) Digital photos of spinning using an IPA coagulation bath.(i) Schematic diagram of stress-strain curves of MXene/PU fibers at different stages. (j) Representing the stress-strain curves of the fibers.(k) Schematic diagram of the fabrication of multiscale disordered poroelastic fibers. (l) Schematic diagram of the thermal stretching method of the stretchable conductive fibers. (m) Electrical properties of the stretchable conductive fibers.

    图  5  (a)PU薄膜、CNTs和CNTs/PU螺旋纱线的热重结果,CNT约占CNTs/PU螺旋纱的11.7%。(b)应用CNTs/PU螺旋纱作为应变传感器,监测手指折叠与(c)臂弯曲。(d)采用PPE纤维作为检测人体运动的传感器。(e)传感器在40%应变循环拉伸装卸下8000次循环的性能。(f)连接在不同部件上的用于检测人体运动的PPE传感器的示意图。(g)光纤传感器的照片和相应的电压信号附着在人体手腕上。

    Figure  5.  (a) Thermogravimetric results of PU films, CNTs and CNTs/PU helical yarns, CNTs accounted for about 11.7% of CNTs/PU helical yarns. (b) CNTs/PU helical yarns were applied as strain sensors to monitor finger folding, (c) The arm is bent. (d) Adoption of PPE fiber as a sensor to detect human motion. (e) Performance of the sensor under 40% strain cyclic tensile loading and unloading for 8000 cycles. (f) Attached to different parts for use in Schematic of a PPE sensor that detects human motion. (g) Photograph of the fiber optic sensor and corresponding voltage signal attached to the human wrist.

    图  6  (a)预定义的手配置和相应的智能手套手势:电话,好,对,和爱 。(b)智能手套上的阻力变化。(c)编织成智能手套的手语和手势识别。预定义字母SCU和T。 (d)输出相对阻力曲线表达字母SCU和T。(e)由纱线制成的储能纺织品的照片。15 cm×10 cm的编织衣服可以照亮30个LED。(f)用图案编织的腕带(插图为LED的图案)。(g) 纺织品的编织示意图。每个接触的发光经纱和透明导电纬线形成一个发光单元(插图)。(h)功能多色显示纺织品在复杂变形下的照片,包括弯曲和扭曲。比例尺,2 cm。(i)多色显示纺织品放大照片显示,EL单元在距离为800μm。比例尺,2 mm。(j)概念图像显示,集成了显示器和键盘的纺织品可以用作一个通信平台。(k)按下编织成纺织品的键,将信息输入到衣服上。比例尺,2厘米,在集成的纺织系统与智能手机之间接收和发送信息。

    Figure  6.  (a) Predefined hand configurations and corresponding smart glove gestures: Phone, Ok, Right, and Love .(b) Resistance variation on the smart glove. (c) Sign language and gesture recognition woven into smart gloves. Predefined letters SCU, and t .(d) Output relative resistance curve expressing letters SCU and t. (e) Photograph of energy storage textiles made of yarns. 15 cm×10 cm woven clothes can illuminate 30 LEDs. (f) Wristbands woven with patterns (inset is the pattern of LEDs). (g) Schematic of the weaving of the textile. Each contacting luminescent warp and transparent conductive weft forms an EL unit (inset). (h) Photo of a functional multicolor display textile under complex deformation, including bending and twisting. Scale bar, 2 cm. (i) Multicolor display textile magnified photo shows EL cells at ~800 μm distance. Scale bar, 2 mm. (j) Concept image shows that a textile with integrated display and keyboard can be used as a communication platform. (k) Pressing keys woven into a textile enters information onto clothing. Scale bar, 2 cm, receiving and sending information between an integrated textile system and a smartphone.

    图  7  (a)导电卷须作为电容应变传感器用于可穿戴传感应用。H型传感器结构示意图。(b)H型传感器横截面的扫描电镜图像。比例尺,500μm。(c)S型传感器通过记录呼吸和转换信号在监测睡眠质量方面的应用。(d)防水导电纤维的制作工艺。(e)防水层微观原理示意图。(f)SAM涂层导电纤维排斥染色水的照片图像。(g)显示螺旋纤维型互连器的制造过程的示意图。(h)3 D打印银支架的示意图及其在螺旋光纤型互连和LED之间形成持久连接的应用。(i,j)在同时应用单轴拉伸(350%)和扭曲(350%)之前,可拉伸的3×3 LED阵列在软弹性基底上的操作。

    Figure  7.  (a) Conductive tendrils as capacitive strain sensors for wearable sensing applications. Schematic diagram of the structure of the H-type sensor. (b) SEM image of the cross-section of the h-type sensor. Scale bar, 500 μm. (c) S-Sensor application in monitoring sleep quality by recording respiration and converting signals. (d) Fabrication process of the waterproof conductive fiber. (e) Schematic diagram of the microscopic principle of the waterproof layer. (f) Photographic image of the sam-coated conductive fiber repelling dyed water. (g) Schematic diagram showing the fabrication process of helical fiber-type interconnects.(h) Schematic diagram of 3 D-printed silver scaffolds and their application to form durable connections between helical fiber-type interconnects and LEDs. (i,j) Operation of a stretchable 3 × 3 LED array on a soft elastic substrate before simultaneous application of uniaxial stretching (350%) and twisting (135°).

    图  8  (a)AgNWs−BC/PDMS的微观结构图像,显示了内部多孔结构。(b)虚线圈表示大孔I和微孔II 。(c)照明LED由AgNWs−BC光纤悬挂2 V电压供电。(d)应变不敏感拉伸电子学的潜在应用,使用GP0@纤维和GP300@纤维作为可拉伸的电子电路。(e,f)使用GP0@纤维和GP300@纤维作为电子电路的LED的照片。(g,h)螺旋橡胶@19层CNTS(NTS19)@纤维的电阻与应变变化。NTS4@橡胶@NTS3@纤维的电容和线性电容(每瞬时长度)的应变依赖性。上插图显示电容变化在选定的周期到950%的应变。下插图显示光纤的结构。(i)使用PPE光纤作为柔性和可拉伸的手机充电电缆。(j)原始的和拉伸的MCP纤维的照片。(k)MCP纤维带结的扫描电镜图像。(l) CNTs含量对CP纤维拉伸性和电导率的影响。

    Figure  8.  (a) Microstructure image of AgNW−BC/PDMS, showing the internal porous structure. (b) Dashed circles indicate macropore I and micropore II. (c) Illumination LEDs are powered by a voltage of 2 V suspended from the AgNW−BC fiber. (d) Potential applications of strain-insensitive tensile electronics using GP0@filament and GP300@filament as stretchable electronic circuits. (e,f) Photographs of LEDs using GP0@filament and GP300@filament as electronic circuits. (g,h) Resistance and strain changes of helical rubber @NTS19@ fibers. Strain dependence of capacitance and linear capacitance (per instantaneous length) of NTS4@rubber@NTS3@ fibers. The inset above shows the capacitance change over the selected cycle to 950% strain. The inset below shows the structure of the fiber. (i) Using PPE fiber as a flexible and stretchable mobile phone charging cable. (j) Photographs of pristine and stretched MCP fibers. (k) SEM image of MCP fiber ribbon knots.(l) Effect of carbon nanotube content on the stretchability and electrical conductivity of CP fibers.

    图  9  (a)固态纱线电池的原理图(b)编织制成的能量腕带为手表(左)、一组LED(右上)和一个脉冲传感器(右下)提供动力。(c)图比较了水电池和非对称超级电容器。(d)FLIB照片,长度为1米。比例尺,1 cm同轴。(e)连续的纤维锂离子电池可以有效满足各种电子产品的用电需求。(f)纤维锂离子电池织物为智能手机进行无线充电。(g)结果表明,即使在500次循环后,容量保留率和库仑效率仍然很高。(h)挤压纤维电池的原理图。三组分(阴极、阳极和电解质)结构继承自喷丝板结构。(i)纤维电池的挤压过程和结构特性。(j)采用纺织太阳能电池的光电充电(红线)和纺织电池的放电曲线(蓝线)。

    Figure  9.  (a) Schematic of a solid-state yarn battery. (b) Woven energy wristband to power a watch (left), a set of LEDs (top right), and a pulse sensor (bottom right). (c) Ragone diagram A comparison of water batteries and asymmetric supercapacitors. (d) Photo with a length of 1 m. Scale bar, 1 cm coaxial. (e) Continuous fiber Li-ion batteries can effectively meet the power demand of various electronic products. (f) Fiber Li-ion battery fabric for wireless charging of smartphones.(g) The results show that the capacity retention and coulombic efficiency are still high even after 500 cycles.(h) Schematic of the extruded fiber battery. The three-component (cathode, anode and electrolyte) structure is inherited from the spinneret structure.(i) Extrusion process and structural properties of the fiber battery. (j) Photoelectric charging (red line) and discharge curves (blue line) of textile solar cells using textile solar cells.

    10b  (a,b)不同的手势对应于不同的模拟显示和测试软件中阻力的相对变化。(c)H型传感器在符号字母表手势翻译中的应用。(d)连接在复合纤维上的智能手套的照片。比例尺:2厘米。(e)英语字母“Y”、“S”、“U”的运动检测,以使用手语手套和检测每个字母的照片。比例尺:3 cm。(f)佩戴前(满载)和正常/运动条件下手腕上可穿戴传感器的响应曲线。(g)可穿戴传感器,当佩戴者说“你好”、“纤维”和“导体”时,响应曲线。(h)自愈人工神经纤维的能量输送能力和快速恢复能力。比例尺:3厘米。(i)传感器在一组手臂运动中的工作过程示意图。右图是监测肌肉力量的图片。(j)主动探测传感器附着在肘部上的图片。(k)弯头分别在30°、60°、90°、120° 时传感器的电压曲线。比例尺:2厘米。

    10b.  (a–b)Different gestures correspond to relative changes in resistance in different simulated displays and test software. (c)Application of the H-type sensor in the translation of symbolic alphabet gestures. (d)Photograph of the smart glove attached to the composite fiber. Scale bar: 2 cm. (e)Motion detection of English letters "Y", "S", "U" to use sign language gloves and to detect photos of each letter. Scale bar: 3 cm. (f)Response curves of the wearable sensor on the wrist before wearing (full load) and under normal/exercise conditions. (g)Wearable sensor response curves when the wearer says "hello", "fiber" and "conductor".(h) Self healing artificial nerve fiber has the ability of energy transmission and rapid recovery. Scale bar: 3 cm. (i) Schematic diagram of the working process of the sensor in a group of arm movements. The picture on the right is a picture of monitoring muscle strength. (j) An image of the active detection sensor attached to the elbow. (k) The voltage curve of the sensor when the elbow is at 30 °, 60 °, 90 ° and 120 ° respectively. Scale bar: 2 cm.

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  • 收稿日期:  2022-03-16
  • 录用日期:  2021-05-03
  • 修回日期:  2021-04-26
  • 网络出版日期:  2022-05-16

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