纳米银导电油墨及其在柔性印刷电子中的应用

目的 探究纳米银导电油墨及其在柔性印刷电子中的应用。方法 通过总结国内外文献,从纳米银颗粒及其导电油墨的制备、印刷工艺、烧结工艺以及在柔性印刷电子技术中的应用几方面总结近年来的研究进展。结果 在油墨制备及使用中,简化制备工艺、降低生产成本、实现绿色环保、低温烧结,同时提高油墨的基材适应性是未来纳米银导电油墨的改进重点。直写技术具有精度高、速度快等优势,正逐渐替代丝网印刷技术成为主流。烧结工艺的研究重点在于实现低温烧结,其中化学烧结工艺简单,但提高导电性是研究重点。其他烧结方式则设备昂贵,环境要求高。结论 作为功能性电子材料,纳米银导电油墨因出色的电性能和印刷适性,正在被广泛应用于柔性印刷电子中。近年来通过对纳米银及其导电油墨的深入研究及技术改进,在纳米银颗粒的制备、低温烧结技术、节能环保加工工艺等方面获得了一定的进展。与此同时,将其作为功能材料应用于制备柔性传感器中,RFID标签天线、柔性电极、超级电容器、太阳能电池等正受到广泛研究与应用。     

Elastic modulus of a silicon thin film fabricated by nanotransfer printing

Transfer printing, a promising method for fabricating multi-scale structures on various substrates such as semiconductors and polymers, has been used to fabricate flexible devices with performance superior to that of conventional organic flexible devices. Although thin films might be expected to suffer damage during the transfer printing process, no reports of the degradation of mechanical properties during transfer printing have been published. The change in mechanical properties before and after transfer printing should be evaluated in terms of reliability and design for transfer printing to be successful. We propose a method of fabricating freestanding 200-nm-thick single-crystal silicon (SCS) thin-film specimens using transfer printing in order to investigate the mechanical properties of the transferred SCS thin-film specimens. The fabrication method combines several techniques such as semiconductor manufacturing, liftoff, and transfer printing processes. The core technology in this method is the fabrication of freestanding SCS thin-film structures suspended between two fixed ends. The mechanical properties of the freestanding SCS thin-film structures were measured using a microtensile machine capable of optical strain measurement. The test results provide insight into device design and reliability evaluation of flexible electronics fabricated by nanotransfer printing.     

镓基液态金属导电油墨及其图形化应用

目的 提出发展液态金属导电油墨的基本途径及其对信息产业发展重要性。方法 从导电油墨的制备方法、液态金属粒子的物理特性、液态金属油墨图形化及其应用展开论述,全面总结液态金属导电油墨的技术现状以及深化对其的认识。结果 液态金属基导电油墨将比目前贵金银基导电油墨的成本低50倍,基于液态金属的导电油墨图形化印刷电子在智能防伪包装、柔性电子、生物医用等领域呈快速发展趋势。结论 镓基液态金属导电油墨及其印刷技术是一个崭新的技术革命,具有重要的研究价值和经济意义。     

液态金属基油墨的印刷适性调控与可拉伸电子应用

目的 调整液态金属基油墨的印刷适性，用于可拉伸电极的印刷法构建。方法 通过超声破碎法减小液态金属微粒直径，降低其表面张力;探究聚氨酯种类和含量对液态金属微粒的分散性、油墨流变性、电极的印刷适性和可拉伸性的影响。结果 引入PU1185制备的液态金属油墨，丝印电极分辨率达58 µm;印制电极展现了良好的导电性和可拉伸性，预拉伸稳定后的电极在100%的应变下拉伸1 000次，电阻变化不超2倍。结论 液态金属基油墨能够用于高分辨电路的加工，在可拉伸电子领域具有可预见的应用前景。     

Deterministic Assembly of Flexible Si/Ge Nanoribbons via Edge‐Cutting Transfer and Printing for van der Waals Heterojunctions

As the promising building blocks for flexible electronics and photonics, inorganic semiconductor nanomembranes have attracted considerable attention owing to their excellent mechanical flexibility and electrical/optical properties. To functionalize these building blocks with complex components, transfer and printing methods in a convenient and precise way are urgently demanded. A combined and controllable approach called edge‐cutting transfer method to assemble semiconductor nanoribbons with defined width (down to submicrometer) and length (up to millimeter) is proposed. The transfer efficiency can be comprehended by a classical cantilever model, in which the difference of stress distributions between forth and back edges is investigated using finite element method. In addition, the vertical van der Waals PN (p‐Si/n‐Ge) junction constructed by a two‐round process presents a typical rectifying behavior. The proposed technology may provide a practical, reliable, and cost‐efficient strategy for transfer and printing routines, and thus expediting its potential applications for roll‐to‐roll productions for flexible devices.     

Printable Transparent Conductive Films for Flexible Electronics

Printed electronics are an important enabling technology for the development of low‐cost, large‐area, and flexible optoelectronic devices. Transparent conductive films (TCFs) made from solution‐processable transparent conductive materials, such as metal nanoparticles/nanowires, carbon nanotubes, graphene, and conductive polymers, can simultaneously exhibit high mechanical flexibility, low cost, and better photoelectric properties compared to the commonly used sputtered indium‐tin‐oxide‐based TCFs, and are thus receiving great attention. This Review summarizes recent advances of large‐area flexible TCFs enabled by several roll‐to‐roll‐compatible printed techniques including inkjet printing, screen printing, offset printing, and gravure printing using the emerging transparent conductive materials. The preparation of TCFs including ink formulation, substrate treatment, patterning, and postprocessing, and their potential applications in solar cells, organic light‐emitting diodes, and touch panels are discussed in detail. The rational combination of a variety of printed techniques with emerging transparent conductive materials is believed to extend the opportunities for the development of printed electronics within the realm of flexible electronics and beyond.     

纤维素导电基底及其柔性电子器件的研究进展

纤维素是自然界中含量丰富且可再生、可降解的天然材料.本文综述了物理、化学、生物或相结合的技术对纤维素的影响作用及可制备的纤维素基元材料,例如纤维素纤维、纳米纤维素和纤维素分子.基于纤维素纤维,利用湿法造纸技术可以生产具有高孔隙率的纤维素纸张基底;基于纳米纤维素,利用真空抽滤或涂布等方式可制备具有低表面粗糙度及高透明度的...     

Large‐Scale Direct‐Writing of Aligned Nanofibers for Flexible Electronics

Nanofibers/nanowires usually exhibit exceptionally low flexural rigidities and remarkable tolerance against mechanical bending, showing superior advantages in flexible electronics applications. Electrospinning is regarded as a powerful process for this 1D nanostructure; however, it can only be able to produce chaotic fibers that are incompatible with the well‐patterned microstructures in flexible electronics. Electro‐hydrodynamic (EHD) direct‐writing technology enables large‐scale deposition of highly aligned nanofibers in an additive, noncontact, real‐time adjustment, and individual control manner on rigid or flexible, planar or curved substrates, making it rather attractive in the fabrication of flexible electronics. In this Review, the ground‐breaking research progress in the field of EHD direct‐writing technology is summarized, including a brief chronology of EHD direct‐writing techniques, basic principles and alignment strategies, and applications in flexible electronics. Finally, future prospects are suggested to advance flexible electronics based on orderly arranged EHD direct‐written fibers. This technology overcomes the limitations of the resolution of fabrication and viscosity of ink of conventional inkjet printing, and represents major advances in manufacturing of flexible electronics.     

Patterned Paper as a Low-Cost, Flexible Substrate for Rapid Prototyping of PDMS Microdevices via "Liquid Molding"

This report describes the use of patterned paper as a low-cost, flexible substrate for rapidly prototyping PDMS microdevices via "liquid molding". The entire fabrication process consists simply of three steps: (1) fabrication of patterned paper in NC membrane by direct wax printing (or modified wax printing that we call "transfer wax printing"); (2) formation of liquid mold on wax-patterned NC membrane; (3) PDMS molding and curing on wax-patterned NC membrane anchored with liquid micropatterns. All these procedures can be finished within only 1.5 h without the use of a photomask, photoresist, UV lamp, etc. Through the use of wax-patterned NC membrane coupled with a liquid mold as a template, different PDMS microdevices such as microwells and microchannels have been fabricated to demonstrate the usefulness of the method for PDMS microfabrication. The height of microwells and microchannels can also be tailored flexibly by adjusting the liquid filling volume. This method for prototyping PDMS microdevices has some favorable merits including simple operation procedures, fast concept-to-device time, and low cost, indicating its potential for simple PDMS microdevice fabrication and applications.     

导电油墨及其印刷技术的研究进展

目的 综述导电油墨及其印刷方式的研究进展,为开发价格低廉、性能稳定、导电性优良的导电油墨提供参考。方法 通过查阅文献归纳各类导电油墨的制备方式、印刷方式和应用领域,对导电油墨进行系统分类,比较各类导电油墨的性能和优缺点,并对其印刷技术进行分析,展望了导电油墨的发展前景。结果 目前关于导电油墨的研究集中在纳米银、纳米铜、石墨烯等导电填料的低温烧结油墨,主要采用丝网印刷、喷墨印刷等印刷方式,多用于制备传感器、柔性可穿戴设备等。未来的研究仍需关注如何低成本、低能耗、简单大量地制造导电油墨。结论 导电油墨的制备将与环境友好型的印刷方式相结合,向高导电性、高印刷适性发展,成为印刷电子领域的关键技术。     

基于知识图谱的柔性版印刷技术应用专利数据挖掘

目的 为了对柔性版印刷关键技术的演进路径及研发热点进行知识挖掘。方法 以德温特专利数据库(DII)收录的柔性版印刷技术相关专利为数据源,借助信息可视化软件CiteSpace对所采集的专利数据进行计量和可视化分析。结果 利用CiteSpace软件提供的词频探测技术绘制了柔性版印刷技术的研发热点和前沿知识图谱,识别了柔印领域的技术热点。通过聚类可以发现专利文献聚焦范围主要集中在印刷版材制作、印刷油墨、印刷设备和柔性印刷电子等领域。研究焦点从最初的柔性版印刷的油墨和喷墨印刷研究领域,逐渐出现了对印版制版的研究,后续又围绕着印刷设备的各个部分产生了新的研发热点,如控制系统、触屏、飞达和装帧部分。结论 基于专利知识图谱分析可以应用到柔性版印刷技术的知识管理过程中,能为柔印行业探测学科前沿、开展知识服务提供决策依据和技术支撑。     

Toward the Development of Printable Nanowire Electronics and Sensors

In recent years, there has been tremendous progress in the research and development of printable electronics on mechanically flexible substrates based on inorganic active components, which provide high performances and stable device operations at low cost. In this regard, various approaches have been developed for the direct transfer or printing of micro‐ and nanoscale, inorganic semiconductors on substrates. In this review article, we focus on the recent advancements in the large‐scale integration of single crystalline, inorganic‐nanowire (NW) arrays for electronic and sensor applications, specifically involving the contact printing of NWs at defined locations. We discuss the advantages, limitations, and the state‐of‐the‐art of this technology, and present an integration platform for future printable, heterogeneous‐sensor circuitry based on NW parallel arrays.     

Ultrathin Crystalline Silicon Nano and Micro Membranes with High Areal Density for Low-Cost Flexible Electronics

Ultrathin crystalline silicon is widely used as an active material for high-performance, flexible, and stretchable electronics, from simple passive and active components to complex integrated circuits, due to its excellent electrical and mechanical properties. However, in contrast to conventional silicon wafer-based devices, ultrathin crystalline silicon-based electronics require an expensive and rather complicated fabrication process. Although silicon-on-insulator (SOI) wafers are commonly used to obtain a single layer of crystalline silicon, they are costly and difficult to process. Therefore, as an alternative to SOI wafers-based thin layers, here, a simple transfer method is proposed for printing ultrathin multiple crystalline silicon sheets with thicknesses between 300 nm to 13 µm and high areal density (>90%) from a single mother wafer. Theoretically, the silicon nano/micro membrane can be generated until the mother wafer is completely consumed. In addition, the electronic applications of silicon membranes are successfully demonstrated through the fabrication of a flexible solar cell and flexible NMOS transistor arrays.     

Printed electronic switch on flexible substrates using printed microcapsules

Printed electronics, the manufacturing of electronic components on large, flexible, and low-cost substrates by printing techniques, can facilitate widespread, very low-cost electronics for consumer applications and disposable devices. New technologies are needed to create functional components in this field. This paper introduces a new method to create an all-additive printed switch on flexible substrate materials, such as polymer foils and paper substrates. The active layer of the switch component consists of neutral polyaniline (PANI), which can be doped by acid to induce a shift from a non-conductive to a conductive oxidation state. Monodisperse core–shell microcapsules containing an acidic aqueous core liquid were produced by a novel inkjet-based encapsulation technology. It was shown that unfavorable water evaporation from the microcapsules could be reduced by the addition of calcium chloride to the core liquid. A switch component was prepared, consisting of inkjet-printed interdigitated silver electrodes, PANI active layer and printed microcapsules. If an external pressure was applied, for instance with a finger, then the switch component changed its state from non-conductive to conductive with a simultaneous distinct color change. The results clearly demonstrate the feasibility of the presented approach to create either a visual or electronic signal for use in printed electronic applications.     

Organic Photovoltaic Cells: From Performance Improvement to Manufacturing Processes

Organic photovoltaics (OPVs) have been pursued as a next generation power source due to their light weight, thin, flexible, and simple fabrication advantages. Improvements in OPV efficiency have attracted great attention in the past decade. Because the functional layers in OPVs can be dissolved in common solvents, they can be manufactured by eco‐friendly and scalable printing or coating technologies. In this review article, the focus is on recent efforts to control nanomorphologies of photoactive layer and discussion of various solution‐processed charge transport and extraction materials, to maximize the performance of OPV cells. Next, recent works on printing and coating technologies for OPVs to realize solution processing are reviewed. The review concludes with a discussion of recent advances in the development of non‐traditional lamination and transfer method towards highly efficient and fully solution‐processed OPV.     

形状记忆聚合物在柔性光/电子器件领域的发展与挑战

随着柔性光/电子技术的不断发展,人们对下一代柔性光/电子器件提出了新的要求。刺激响应型材料尤其是形状记忆聚合物（Shape memory polymer,SMP）近年来得到了广泛的关注与发展。将SMP与柔性光/电子结合不仅能够赋予柔性光/电子器件形状记忆功能,而且还能极大拓展柔性光/电子器件的功能性和应用范围。本文首先综述了使用SMP基板赋予柔性光/电子器件形状记忆功能的SMP种类、驱动方法、制备技术及应用领域;其次综述了具有显著优势的4D打印技术打印的三维SMP结构器件的种类、所使用的SMP原材料、驱动方法及应用领域;最后展望了形状记忆柔性光/电子器件未来发展方向和遇到的挑战。     

Graphene oxide thin films for flexible nonvolatile memory applications

There has been strong demand for novel nonvolatile memory technology for low-cost, large-area, and low-power flexible electronics applications. Resistive memories based on metal oxide thin films have been extensively studied for application as next-generation nonvolatile memory devices. However, although the metal oxide based resistive memories have several advantages, such as good scalability, low-power consumption, and fast switching speed, their application to large-area flexible substrates has been limited due to their material characteristics and necessity of a high-temperature fabrication process. As a promising nonvolatile memory technology for large-area flexible applications, we present a graphene oxide based memory that can be easily fabricated using a room temperature spin-casting method on flexible substrates and has reliable memory performance in terms of retention and endurance. The microscopic origin of the bipolar resistive switching behavior was elucidated and is attributed to rupture and formation of conducting filaments at the top amorphous interface layer formed between the graphene oxide film and the top Al metal electrode, via high-resolution transmission electron microscopy and in situ X-ray photoemission spectroscopy. This work provides an important step for developing understanding of the fundamental physics of bipolar resistive switching in graphene oxide films, for the application to future flexible electronics.     

Highly Flexible Hybrid CMOS Inverter Based on Si Nanomembrane and Molybdenum Disulfide

2D semiconductor materials are being considered for next generation electronic device application such as thin‐film transistors and complementary metal–oxide–semiconductor (CMOS) circuit due to their unique structural and superior electronics properties. Various approaches have already been taken to fabricate 2D complementary logics circuits. However, those CMOS devices mostly demonstrated based on exfoliated 2D materials show the performance of a single device. In this work, the design and fabrication of a complementary inverter is experimentally reported, based on a chemical vapor deposition MoS₂ n‐type transistor and a Si nanomembrane p‐type transistor on the same substrate. The advantages offered by such CMOS configuration allow to fabricate large area wafer scale integration of high performance Si technology with transition‐metal dichalcogenide materials. The fabricated hetero‐CMOS inverters which are composed of two isolated transistors exhibit a novel high performance air‐stable voltage transfer characteristic with different supply voltages, with a maximum voltage gain of ≈16, and sub‐nano watt power consumption. Moreover, the logic gates have been integrated on a plastic substrate and displayed reliable electrical properties paving a realistic path for the fabrication of flexible/transparent CMOS circuits in 2D electronics.     

水披覆转印的研究进展

水披覆转印工艺包括水转印膜的制作、水转印和后处理3个部分,主要材料有载体薄膜、印刷油墨、油墨活化剂及底漆与面漆,其印刷方式一般采用传统的凹版印刷。水披覆转印的载体薄膜一般为水溶性PVA薄膜,油墨通常为溶剂型油墨,活化剂主要是以芳香烃为主的有机混合溶剂。以水性油墨替代溶剂型油墨、无毒活化剂替代有毒或微毒活化剂、彩色喷墨印刷方式替代传统的凹版印刷方式等绿色环保、生产效率高的水披覆转印技术是今后水转印技术的研究方向与重点。     

Highly Transparent Conducting Nanopaper for Solid State Foldable Electrochromic Devices

It is of great challenge to develop a transparent solid state electrochromic device which is foldable at the device level. Such devices require delicate designs of every component to meet the stringent requirements for transparency, foldability, and deformation stability. Meanwhile, nanocellulose, a ubiquitous natural resource, is attracting escalating attention recently for foldable electronics due to its extreme flexibility, excellent mechanical strength, and outstanding transparency. In this article, transparent conductive nanopaper delivering the state‐of‐the‐art electro‐optical performance is achieved with a versatile nanopaper transfer method that facilitates junction fusing for high‐quality electrodes. The highly compliant nanopaper electrode with excellent electrode quality, foldability, and mechanical robustness suits well for the solid state electrochromic device that maintains good performance through repeated folding, which is impossible for conventional flexible electrodes. A concept of camouflage wearables is demonstrated using gloves with embedded electrochromics. The discussed strategies here for foldable electrochromics serve as a platform technology for futuristic deformable electronics.