Flexible Transparent(灵活透明)研究综述
Flexible Transparent 灵活透明 - Networks of metal nanowires are candidates for flexible transparent and conductive films, however the microand nanomechanical behaviour of nanowires is still only partially understood. [1] A flexible transparent is an important technology to improve flexible electronic and flexible display devices. [2]金属纳米线网络是柔性透明和导电薄膜的候选者,但是纳米线的微观和纳米机械行为仍然只是部分了解。 [1] 柔性透明体是改进柔性电子和柔性显示器件的重要技术。 [2]
indium tin oxide 氧化铟锡
Poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) films have drawn extensive attention as one of the most promising flexible transparent conductive electrodes to replace traditional indium tin oxide. [1] The bilayer structure of poly(3,4-ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) coating on silver nanowires (AgNWs) film is a promising structure for replacing indium tin oxide (ITO) as a flexible transparent conductive electrode. [2] Flexible transparent electrodes (FTEs) with an embedded metal mesh are considered a promising alternative to traditional indium tin oxide (ITO) due to their excellent photoelectric performance, surface roughness, and mechanical and environmental stability. [3] Metal mesh-based flexible transparent conductive electrodes have attracted much interest as one alternative to conventional indium tin oxide electrodes. [4] A multidimensional graphene and ZnO-based heterostructure for flexible transparent ultraviolet photodetector (UV-PD) applications is successfully fabricated on an indium tin oxide-coated polyethylene terephthalate substrate (ITO-coated PET). [5] Low-cost flexible transparent conductive films (TCFs) with direct writing of metal grids have been explored as a promising alternative to conventional indium-tin-oxide-based TCFs for future flexible electronics. [6]聚(3,4-乙烯二氧噻吩):聚(苯乙烯磺酸盐)(PEDOT:PSS)薄膜作为最有希望替代传统氧化铟锡的柔性透明导电电极之一而受到广泛关注。 [1] 在银纳米线 (AgNWs) 薄膜上涂覆的聚 (3,4-乙烯二氧噻吩): 聚 (苯乙烯磺酸盐) (PEDOT:PSS) 的双层结构是替代氧化铟锡 (ITO) 作为柔性透明导电电极的有前景的结构。 [2] nan [3] nan [4] nan [5] nan [6]
replace indium tin 替代铟锡
Silver nanowire (Ag NW) has been considered as the best material to replace indium tin oxide (ITO) to fabricate flexible transparent electromagnetic interference (EMI) shielding films due to its superior comprehensive performance. [1] Silver nanowires (Ag NWs) are currently the most likely to replace indium tin oxide (ITO) as flexible transparent conducting electrodes (FTCEs), but conventional preparation methods such as solution deposition will lead to weak conductivity and low adhesion to the substrate. [2] The booming market of flexible electronic displays has urged the development of highly flexible transparent conductive electrodes (FTCE)1–3 with the ability to replace indium tin oxide (ITO) thin films routinely used as transparent conductive electrodes in photoelectronic devices. [3]银纳米线 (Ag NW) 因其优越的综合性能被认为是替代氧化铟锡 (ITO) 制备柔性透明电磁干扰 (EMI) 屏蔽膜的最佳材料。 [1] 银纳米线(Ag NWs)是目前最有可能取代氧化铟锡(ITO)作为柔性透明导电电极(FTCEs)的材料,但溶液沉积等常规制备方法会导致导电性弱、对基板的附着力低。 [2] nan [3]
organic light emitting 有机发光
ABSTRACT Development of flexible transparent organic light-emitting devices (TOLEDs) still requires a number of advancements in transparent conducting electrodes with low reflection and absorption, a capping layer (CL) acting as refractive index-matching, and thin film encapsulation (TFE) with high water vapor barrier properties, among others. [1] In the final section, we evaluate three applications of flexible transparent conductors in: perovskite-based solar cells, organic light emitting diodes and electrochromic windows. [2] In this study, the performance stability of solution-processed flexible organic light-emitting diodes (f-OLEDs) in relation to the mechanical stability of their flexible transparent electrode (f-TE) bottom anodes and component functional layers was analyzed. [3]摘要 柔性透明有机发光器件 (TOLED) 的开发仍需要在具有低反射和吸收的透明导电电极、充当折射率匹配的覆盖层 (CL) 和薄膜封装 (TFE) 方面取得一些进展。高水蒸气阻隔性能等。 [1] 在最后一部分中,我们评估了柔性透明导体在钙钛矿基太阳能电池、有机发光二极管和电致变色窗中的三种应用。 [2] nan [3]
low sheet resistance 低薄层电阻
In this study, we present a new and simple method that utilizes post-processing such as thermal treatment and mechanical compression to manufacture a grid patterned silver nanowire (AgNW) flexible transparent electrode with low sheet resistance, high transmittance, and high flexibility. [1] To keep up with the progress in wearable electronics, it is imperative to create flexible transparent heaters with low sheet resistance and high transmittance. [2] The flexible transparent conductive electrode fabricated with AgNWs exhibits outstanding mechanical flexibility and optoelectronic performance with a low sheet resistance of 9. [3]在这项研究中,我们提出了一种新的简单方法,该方法利用热处理和机械压缩等后处理来制造具有低薄层电阻、高透射率和高柔韧性的网格图案化银纳米线 (AgNW) 柔性透明电极。 [1] 为了跟上可穿戴电子设备的发展步伐,开发具有低薄层电阻和高透光率的柔性透明加热器势在必行。 [2] nan [3]
Performance Flexible Transparent 性能 灵活 透明
This work presents various opportunities for developing high-performance flexible transparent electronics based on emerging ultrathin TCO candidates. [1] High-performance flexible transparent p-CuI films were prepared on polycarbonate substrates at room temperature by combining solid iodization and vacuum thermal evaporation. [2] The full room-temperature process further demonstrates the great potential of applying the proposed devices and the PIF platform to future high-performance flexible transparent electronics. [3] This work demonstrated that the flexible composite electrodes of PET/Ag-mesh/PH1000:AgNWs are promising alternatives for the conventional PET/ITO electrode, and open a new avenue for developing high-performance flexible transparent electrode for optoelectronic devices. [4]这项工作为基于新兴的超薄 TCO 候选物开发高性能柔性透明电子产品提供了各种机会。 [1] 通过结合固体碘化和真空热蒸发,在室温下在聚碳酸酯基板上制备了高性能柔性透明 p-CuI 薄膜。 [2] nan [3] nan [4]
Promising Flexible Transparent 有希望 灵活 透明
Poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) films have drawn extensive attention as one of the most promising flexible transparent conductive electrodes to replace traditional indium tin oxide. [1] Graphene is a promising flexible transparent electrode, and significant progress in graphene-based optoelectronic devices has been accomplished by reducing the sheet resistance and tuning the work function. [2] Silver nanowires (AgNWs) have been considered as one of the most promising flexible transparent electrodes (FTEs) material for next-generation optoelectronic devices. [3] Electrospun metal fiber is a promising flexible transparent electrode owing to its extremely long length and facile fabrication process. [4]聚(3,4-乙烯二氧噻吩):聚(苯乙烯磺酸盐)(PEDOT:PSS)薄膜作为最有希望替代传统氧化铟锡的柔性透明导电电极之一而受到广泛关注。 [1] 石墨烯是一种很有前途的柔性透明电极,通过降低薄层电阻和调整功函数,基于石墨烯的光电器件取得了重大进展。 [2] nan [3] nan [4]
Highly Flexible Transparent
The broad application of flexible optoelectronic devices is still hampered by the lack of an ITO-free and highly flexible transparent electrode. [1] The booming market of flexible electronic displays has urged the development of highly flexible transparent conductive electrodes (FTCE)1–3 with the ability to replace indium tin oxide (ITO) thin films routinely used as transparent conductive electrodes in photoelectronic devices. [2] The present work, describes a ‘green’ method to fabricate a biodegradable and highly flexible transparent wood-polymer composite from poplar wood veneers and polyvinyl alcohol (PVA). [3]柔性光电器件的广泛应用仍因缺乏不含 ITO 且高度柔性的透明电极而受到阻碍。 [1] nan [2] nan [3]
Area Flexible Transparent
Summary Designing large-area flexible transparent smart windows for high-efficiency indoor fine particulate matter (PM2. [1] In order to realize the mass production of the large-area flexible transparent film heater (FTFH) at low-cost, this paper presents a novel method which can achieve the direct fabrication of the large-area FTFH with Ag-grid by using an electric-field-driven jet deposition micro-scale 3D printing. [2]Generation Flexible Transparent 代灵活透明
Furthermore, the good heat and corrosion resistivity of these Al-based amorphous thin films makes them extremely promising as next-generation flexible transparent electrodes used under various environment. [1] PEDOT:PSS-based conductive films have emerged as promising next-generation flexible transparent electrodes. [2]此外,这些铝基非晶薄膜良好的耐热性和耐腐蚀性使其非常有希望作为在各种环境下使用的下一代柔性透明电极。 [1] PEDOT:PSS 基导电薄膜已成为有前途的下一代柔性透明电极。 [2]
flexible transparent electrode 柔性透明电极
Flexible film heaters on plastic substrate is also demonstrated, suggesting a great potential of the solvent treatment process of Ag NWs for flexible transparent electrode and film heater applications. [1] Furthermore, the good heat and corrosion resistivity of these Al-based amorphous thin films makes them extremely promising as next-generation flexible transparent electrodes used under various environment. [2] PEDOT:PSS-based conductive films have emerged as promising next-generation flexible transparent electrodes. [3] The solution-processed flexible transparent electrode of AgNWs:PEI-Zn shows low surface roughness and good optoelectronic and mechanical properties. [4] The broad application of flexible optoelectronic devices is still hampered by the lack of an ITO-free and highly flexible transparent electrode. [5] 73% at 550 nm and a reduction in the sheet resistance were achieved using this plasma annealing from 1105 Ω/□ to 535 Ω/□ on the ITO/PEDOT:PSS nano composite making them excellent candidates to develop as cost effective flexible transparent electrodes that can be used as thin film heaters. [6] Graphene is a promising flexible transparent electrode, and significant progress in graphene-based optoelectronic devices has been accomplished by reducing the sheet resistance and tuning the work function. [7] In this study, indium-zinc oxide (IZO)/silver (Ag)/IZO (ZAZ) flexible transparent electrodes were prepared on polyethylene terephthalate substrate using radio frequency sputtering technique. [8] Flexible transparent electrodes (FTEs) play an important role in determining the performance of flexible organic solar cells (OSCs), Ag-nanowires (AgNWs) with the unique merits of high conductivity, excellent flexibility, and good thermal stability has been taken into more consideration in fabricating highly efficient FTEs. [9] Semi-crystalline graphene has the possible application of being flexible transparent electrodes, and the 3D shaping opens the possibility of more complex configurations and applications. [10] ABSTRACT Flexible transparent electrode is an irreplaceable part of flexible solar cells. [11] With the rapid development of flexible electronic devices (especially flexible LCD/OLED), flexible transparent electrodes (FTEs) with high light transmittance, high electrical conductivity, and excellent stretchability have attracted extensive attention from researchers and businesses. [12] Silver nanowires (AgNWs) have been considered as one of the most promising flexible transparent electrodes (FTEs) material for next-generation optoelectronic devices. [13] Many efforts have been made to improve the performance of flexible OSCs, including the development of flexible transparent electrodes, new organic materials, and optimization of the device structure. [14] Silver nanowires (Ag-NWs), which possess a high aspect ratio with superior electrical conductivity and transmittance, show great promise as flexible transparent electrodes (FTEs) for future electronics. [15] Silver nanowire (AgNW) networks are among the most promising indium-free, flexible transparent electrodes for energy, lighting and heating devices. [16] Flexible transparent electrodes (FTEs) with an embedded metal mesh are considered a promising alternative to traditional indium tin oxide (ITO) due to their excellent photoelectric performance, surface roughness, and mechanical and environmental stability. [17] Although copper nanowires (Cu NWs) flexible transparent electrodes (FTEs) have been considered as one of the most promising candidates for next-generation flexible electronics, its instinct electrochemical instability hindered its application in flexible electrochemical energy system, including EES device. [18] In this study, we present a new and simple method that utilizes post-processing such as thermal treatment and mechanical compression to manufacture a grid patterned silver nanowire (AgNW) flexible transparent electrode with low sheet resistance, high transmittance, and high flexibility. [19] The result exhibits the grain boundary effect of graphene on soft substrates on a macroscopic scale and a great promise toward realizing a tremendous performance improvement of graphene-based flexible transparent electrodes on a large scale. [20] A new ultrafast laser direct writing process to fabricate completely embedded silver mesh flexible transparent electrodes (TEs) using sputtered silver thin films and their applications for flexible transparent heaters (FTHs) are reported. [21] Highly oriented woven Ag-NW grids has great potential for enhancing the mechanical stabilities of flexible transparent electrodes (TEs) but few researchers reported. [22] Specifically, we considered that to elevate the performance of FPSCs, it is crucial to substantially improve film quality of each functional layer, develop more boost encapsulation approach and explore flexible transparent electrodes with high conductivity, transmittance, low cost and expandable processability. [23] This is due, in particular, to the lack of flexible transparent electrodes that simultaneously offer low resistance, high transparency and a smooth surface. [24] Using this method, flexible transparent electrodes were constructed on Cu micromesh-patterned plastic films with transmittance values higher than 75% and sheet resistance values below 0. [25] The lithographic process for flexible transparent electrodes is essential for constructing wearable optoelectronic devices with a well-defined active area. [26] The mechanical responses under cyclic bending of Ag nanowire composite electrodes coated with various metal oxide films of different thicknesses were explored, in an attempt to evaluate their applicability to flexible transparent electrodes. [27] A novel flexible transparent electrode (TE) having a trilayer-stacked geometry and high optoelectronic performance and operational stability was fabricated by the spin coating method. [28] By making aligned and suspended copper nanowires, a high performance, transferable, and flexible transparent electrode is reported. [29] Metal nanonetworks fabricated by chemical plating of metals on electrospun polymer nanofiber network templates have come into the spotlight for use as flexible transparent electrodes. [30] The application of metal grids as flexible transparent electrodes (FTEs) in optoelectronic devices is significantly influenced by poor adhesion and thickness difference between metal and substrate, resistance distribution uniformity and high annealing temperature. [31] In this study, the performance stability of solution-processed flexible organic light-emitting diodes (f-OLEDs) in relation to the mechanical stability of their flexible transparent electrode (f-TE) bottom anodes and component functional layers was analyzed. [32] Electrospun metal fiber is a promising flexible transparent electrode owing to its extremely long length and facile fabrication process. [33] Highly robust and smooth silver nanowire flexible transparent electrodes (AgNW FTEs) with UV-curable polymeric resin as an overcoating layer were fabricated via successive Mayer rod method followed by UV light curing process, and the mechanical and chemical stabilities, electromagnetic interference shielding effectiveness (EMI SE) and film-heating property of the resultant overcoated AgNW FTEs were investigated. [34] This work demonstrated that the flexible composite electrodes of PET/Ag-mesh/PH1000:AgNWs are promising alternatives for the conventional PET/ITO electrode, and open a new avenue for developing high-performance flexible transparent electrode for optoelectronic devices. [35] Therefore, it is estimated that O2 plasma-treated and AgNW-coated fabrics and films can be applied to high-function smart wear, flexible transparent electrode materials, information and communication technology, and the Internet of Things(IoT). [36] The bilayer consists of two elements: (i) a nanoscale gate consisting of a layer of well-defined polypyridyl ruthenium complexes bound to a flexible transparent electrode, and (ii) a charge storage layer consisting of isostructural iron complexes attached to the surface of the gate. [37] Among recent explorations of flexible transparent electrodes (FTEs) applied in photoelectric devices, Ag nanowires (AgNWs) are widely used due to the advantages of high conductivity, large-scale manufacture and superior flexibility. [38] Finally, the deposition methods used open the way towards stable, low-cost and flexible transparent electrodes for industrial applications. [39]还展示了塑料基板上的柔性薄膜加热器,表明 Ag NW 的溶剂处理工艺在柔性透明电极和薄膜加热器应用中具有巨大潜力。 [1] 此外,这些铝基非晶薄膜良好的耐热性和耐腐蚀性使其非常有希望作为在各种环境下使用的下一代柔性透明电极。 [2] PEDOT:PSS 基导电薄膜已成为有前途的下一代柔性透明电极。 [3] nan [4] 柔性光电器件的广泛应用仍因缺乏不含 ITO 且高度柔性的透明电极而受到阻碍。 [5] nan [6] 石墨烯是一种很有前途的柔性透明电极,通过降低薄层电阻和调整功函数,基于石墨烯的光电器件取得了重大进展。 [7] 在这项研究中,采用射频溅射技术在聚对苯二甲酸乙二醇酯基板上制备了铟锌氧化物(IZO)/银(Ag)/IZO(ZAZ)柔性透明电极。 [8] 柔性透明电极(FTEs)在决定柔性有机太阳能电池(OSCs)的性能方面发挥着重要作用,Ag纳米线(AgNWs)以其高导电性、优异的柔韧性和良好的热稳定性等独特优点被更多地考虑制造高效的 FTE。 [9] 半结晶石墨烯具有作为柔性透明电极的可能应用,并且3D成型打开了更复杂配置和应用的可能性。 [10] nan [11] 随着柔性电子器件(尤其是柔性LCD/OLED)的快速发展,具有高透光率、高导电性和优异拉伸性的柔性透明电极(FTE)引起了研究人员和企业的广泛关注。 [12] nan [13] 为了提高柔性 OSC 的性能,人们做出了很多努力,包括开发柔性透明电极、新型有机材料和优化器件结构。 [14] 银纳米线 (Ag-NWs) 具有高纵横比、优异的导电性和透射率,在未来电子产品中显示出作为柔性透明电极 (FTE) 的巨大潜力。 [15] 银纳米线 (AgNW) 网络是用于能源、照明和加热设备的最有前途的无铟柔性透明电极之一。 [16] nan [17] 尽管铜纳米线 (Cu NWs) 柔性透明电极 (FTE) 被认为是下一代柔性电子产品最有希望的候选者之一,但其本能的电化学不稳定性阻碍了其在柔性电化学能源系统中的应用,包括 EES 器件。 [18] 在这项研究中,我们提出了一种新的简单方法,该方法利用热处理和机械压缩等后处理来制造具有低薄层电阻、高透射率和高柔韧性的网格图案化银纳米线 (AgNW) 柔性透明电极。 [19] 该结果在宏观尺度上展示了石墨烯对软基板的晶界效应,并有望在大规模上实现基于石墨烯的柔性透明电极的巨大性能改进。 [20] nan [21] 高度定向的编织 Ag-NW 网格在增强柔性透明电极 (TE) 的机械稳定性方面具有巨大潜力,但很少有研究人员报道。 [22] nan [23] nan [24] nan [25] nan [26] nan [27] nan [28] nan [29] nan [30] nan [31] nan [32] nan [33] nan [34] nan [35] nan [36] nan [37] nan [38] nan [39]
flexible transparent conductive 柔性透明导电
Ag nanowire suspensions are one of the indispensable materials in the design and fabrication of flexible transparent conductive films. [1] Flexible transparent conductive films (FTCFs) have attracted tremendous concern because it is a key component of next generation electronics and optoelectronic devices. [2] Poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) films have drawn extensive attention as one of the most promising flexible transparent conductive electrodes to replace traditional indium tin oxide. [3] The results from this study of curved-mechanical characteristic measurements of flexible transparent conductive substrates can provide designers with improved product development and can assist manufacturers in improving the manufacturing design of enhanced coating processes. [4] Metal grids have great potential in flexible transparent conductive electrodes (E-TCEs) due to their high conductivity and transparency. [5] Flexible transparent conductive electrodes (FTCEs) have received a great deal of attention for various applications due to their versatile ability. [6] The bilayer structure of poly(3,4-ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) coating on silver nanowires (AgNWs) film is a promising structure for replacing indium tin oxide (ITO) as a flexible transparent conductive electrode. [7] Further, AgNWs flexible transparent conductive films were fabricated by using inkjet printing process on the PET substrate, and the effects of the number printing layer, heat treatment temperature, drop frequency, and number of nozzle on the microstructures and photoelectric properties of AgNWs films were investigated in detail. [8] Reliable flexible transparent conductive electrodes (TCEs) and high stability at the perovskite/transport layers interface are vital for increasing the performance of flexible- and stable-PSCs. [9] Carbon nanotubes (CNTs) and graphene (Gr) are promising materials for flexible transparent conductive films (TCFs) in optoelectronic application because of their exceptional electrical, optical, and mechanical properties. [10] The WO3@AgNW-PrePDMS electrode displays outstanding electrochemical stabilities and excellent bi-functionalities (flexible conductive film and electrochromic electrode): high conductivity (12 Ω/sq) as flexible transparent conductive film and wide optical modulation range (ΔT = 72% at 550 nm) as electrochromic electrode. [11] Metal mesh-based flexible transparent conductive electrodes have attracted much interest as one alternative to conventional indium tin oxide electrodes. [12] High-power impulse magnetron sputtering (HiPIMS) was used to deposit ITO/Ag/ITO (IAgI) and ITO/Cu/ITO (ICuI) sandwiched films on polyethylene naphthalate substrate at room temperature as flexible transparent conductive materials. [13] Flexible transparent conductive electrode (FTCE) is highly desirable due to the fast-growing flexible optoelectronic devices. [14] Silver nanowires (AgNWs) are promising candidate materials for flexible transparent conductive films (FTCFs), which are key parts in fabricating flexible optoelectronic devices. [15] The experimental results show that flexible transparent conductive patterns with a light transmittance of 550 nm of 83. [16] Silver nanowire films as a kind of bright flexible transparent conductive material are expected to have the sheet resistance as low as possible, the critically high optical transmittance and the wide range haze for different applications. [17] Facile strategies in flexible transparent conductive electrode materials that can sustain their electrical conductivities under 1 mm-scale radius of curvature are required for wider applications such as foldable devices. [18] In most electronic devices such as flexible transparent conductive electrodes, silver nanowires (AgNWs) need to be patterned with time-consuming processing. [19] In this paper, we systematically investigated the effects of concentration and amount of silver nanowires (AgNWs) suspension on the optoelectronic properties and microstructures of flexible transparent conductive films (FTCFs) composed of AgNWs with an average diameter of about 25 nm and length of 15. [20] The unstable mechanical properties of flexible transparent conductive films (TCFs) make it difficult for them to meet the requirements for displays or wearable devices. [21] The booming market of flexible electronic displays has urged the development of highly flexible transparent conductive electrodes (FTCE)1–3 with the ability to replace indium tin oxide (ITO) thin films routinely used as transparent conductive electrodes in photoelectronic devices. [22] In order to improve the performance of silver nanowire (AgNW) flexible transparent conductive films (FTCFs), including the conductivity, uniformity, and reliability, the welding of high repetition rate femtosecond (fs) laser is applied in this work. [23] In this study, we fabricated ITO-free flexible ECDs by using flexible transparent conductive electrodes (TCE) based on silver nanowires (AgNWs) and poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) on a polyethylene terephthalate (PET) substrate (PEDOT:PSS/AgNW/PET). [24] Low-cost flexible transparent conductive films (TCFs) with direct writing of metal grids have been explored as a promising alternative to conventional indium-tin-oxide-based TCFs for future flexible electronics. [25] Flexible transparent conductive film (TCF) is an important component in many modern smart devices. [26] Graphene exhibits properties of atomic thickness, high transparency, and high carrier mobility, which is highly desirable for a flexible transparent conductive material. [27] The flexible transparent conductive electrode fabricated with AgNWs exhibits outstanding mechanical flexibility and optoelectronic performance with a low sheet resistance of 9. [28]Ag纳米线悬浮液是柔性透明导电薄膜设计和制造中不可缺少的材料之一。 [1] 柔性透明导电薄膜 (FTCF) 是下一代电子和光电器件的关键组成部分,因此引起了极大的关注。 [2] 聚(3,4-乙烯二氧噻吩):聚(苯乙烯磺酸盐)(PEDOT:PSS)薄膜作为最有希望替代传统氧化铟锡的柔性透明导电电极之一而受到广泛关注。 [3] 这项对柔性透明导电基板的弯曲机械特性测量的研究结果可以为设计人员提供改进的产品开发,并可以帮助制造商改进增强涂层工艺的制造设计。 [4] 金属网格由于其高导电性和透明性,在柔性透明导电电极 (E-TCE) 中具有巨大潜力。 [5] 柔性透明导电电极 (FTCE) 由于其多功能性而在各种应用中受到了极大的关注。 [6] 在银纳米线 (AgNWs) 薄膜上涂覆的聚 (3,4-乙烯二氧噻吩): 聚 (苯乙烯磺酸盐) (PEDOT:PSS) 的双层结构是替代氧化铟锡 (ITO) 作为柔性透明导电电极的有前景的结构。 [7] nan [8] nan [9] 碳纳米管 (CNT) 和石墨烯 (Gr) 因其优异的电学、光学和机械性能而成为光电应用中用于柔性透明导电薄膜 (TCF) 的有前途的材料。 [10] WO3@AgNW-PrePDMS 电极显示出出色的电化学稳定性和出色的双功能(柔性导电膜和电致变色电极):作为柔性透明导电膜的高电导率 (12Ω/sq) 和宽光调制范围 (ΔT = 72% at 550 nm) 作为电致变色电极。 [11] nan [12] 高功率脉冲磁控溅射 (HiPIMS) 用于在室温下在聚萘二甲酸乙二醇酯基板上沉积 ITO/Ag/ITO (IAgI) 和 ITO/Cu/ITO (ICuI) 夹层薄膜作为柔性透明导电材料。 [13] 由于快速增长的柔性光电器件,柔性透明导电电极(FTCE)非常受欢迎。 [14] 银纳米线 (AgNWs) 是柔性透明导电薄膜 (FTCFs) 的候选材料,是制造柔性光电器件的关键部件。 [15] 实验结果表明,柔性透明导电图案在 550 nm 处的透光率为 83。 [16] nan [17] 对于可折叠设备等更广泛的应用,需要采用灵活的透明导电电极材料策略,使其导电率保持在 1 毫米尺度的曲率半径以下。 [18] 在大多数电子设备中,例如柔性透明导电电极,银纳米线 (AgNW) 需要通过耗时的处理进行图案化。 [19] nan [20] nan [21] nan [22] nan [23] nan [24] nan [25] nan [26] nan [27] nan [28]
flexible transparent electronic 柔性透明电子
As a result, it can be inferred that diffusion-induced enhanced carrier transporting mechanism is an economical and effective method to optimize the electrical performance of solution-derived InZnO/DyOx TFTs, indicating its potential application prospects in flexible transparent electronics with low power consumption. [1] The flourishing metal-oxide high-k dielectric materials have been regarded as the vital components of low voltage operated flexible transparent electronic devices. [2] This work presents various opportunities for developing high-performance flexible transparent electronics based on emerging ultrathin TCO candidates. [3] The challenges of making high-performance, low-temperature processed, p-type transparent conductors (TCs) have been the main bottleneck for the development of flexible transparent electronics. [4] The full room-temperature process further demonstrates the great potential of applying the proposed devices and the PIF platform to future high-performance flexible transparent electronics. [5] ALD doped ZnO is viewed as a transparent conducting oxide for application in solar cells, flexible transparent electronics, and light-emitting diodes. [6]因此,可以推断扩散诱导的增强载流子传输机制是优化溶液衍生的 InZnO/DyOx TFT 电性能的一种经济有效的方法,表明其在低功耗柔性透明电子产品中的潜在应用前景。 [1] 蓬勃发展的金属氧化物高k介电材料已被视为低压操作柔性透明电子器件的重要组成部分。 [2] 这项工作为基于新兴的超薄 TCO 候选物开发高性能柔性透明电子产品提供了各种机会。 [3] nan [4] nan [5] nan [6]
flexible transparent heater 柔性透明加热器
Flexible transparent heaters based on photothermal energy conversion are highly desired for next-generation electronic devices. [1] Finally, a flexible transparent heater employing a hybrid film is realized. [2] In addition, the successful implementation of the flexible transparent heater demonstrates the practical application value of the electrode. [3] We believe that the results of this study is useful in the development of flexible transparent heaters, including lightweight deicing/defogging films, wearable sensors/actuators, and medical thermotherapy pads. [4] A flexible transparent heater was developed using the reported binary colloidal paste. [5] To keep up with the progress in wearable electronics, it is imperative to create flexible transparent heaters with low sheet resistance and high transmittance. [6]下一代电子设备非常需要基于光热能转换的柔性透明加热器。 [1] 最后,实现了一种采用混合膜的柔性透明加热器。 [2] 此外,柔性透明加热器的成功实现展示了电极的实际应用价值。 [3] 我们相信,这项研究的结果有助于开发柔性透明加热器,包括轻质除冰/除雾膜、可穿戴传感器/执行器和医用温疗垫。 [4] 使用报道的二元胶体糊开发了一种柔性透明加热器。 [5] 为了跟上可穿戴电子设备的发展步伐,开发具有低薄层电阻和高透光率的柔性透明加热器势在必行。 [6]
flexible transparent conducting 柔性透明导电
Silver nanowires (Ag NWs) are currently the most likely to replace indium tin oxide (ITO) as flexible transparent conducting electrodes (FTCEs), but conventional preparation methods such as solution deposition will lead to weak conductivity and low adhesion to the substrate. [1] Ultra-thin and continuous metallic silver films are attracting growing interest due to the applications in flexible transparent conducting electrodes. [2] We demonstrated extraordinary easy and low-cost fabrication of flexible transparent conducting film (TCF) using graphite powder as conducting material. [3] Herein, the layer-dependent electrical and optical properties of RuO2 nanosheets films have been investigated for the application of the flexible transparent conducting electrodes due to their superior optical properties. [4] Metal mesh is a promising material for flexible transparent conducting electrodes due to its outstanding physical and electrical properties. [5]银纳米线(Ag NWs)是目前最有可能取代氧化铟锡(ITO)作为柔性透明导电电极(FTCEs)的材料,但溶液沉积等常规制备方法会导致导电性弱、对基板的附着力低。 [1] 由于在柔性透明导电电极中的应用,超薄且连续的金属银膜引起了越来越多的关注。 [2] nan [3] nan [4] nan [5]
flexible transparent film 柔性透明薄膜
On this basis, the masking of PVA/Gd2O3:Eu3+ (5 mol %)@BSA solution on a latent fingerprints results a flexible transparent film; a highly stable fingerprint images with well-defined ridge characteristics was developed on the film, which enabling personal individualization. [1] Flexible transparent film heaters (FTHs) are used in a variety of applications, including smart windows and wearable devices, because they are transparent to visible light while generating Joule heat. [2] Ultrathin flexible transparent film heaters (TFHs) with fast response time are fabricated by embedding single-wall carbon nanotubes (CNTs) into transparent poly(vinyl alcohol) (PVA) film using a green all-water based solution process. [3] In order to realize the mass production of the large-area flexible transparent film heater (FTFH) at low-cost, this paper presents a novel method which can achieve the direct fabrication of the large-area FTFH with Ag-grid by using an electric-field-driven jet deposition micro-scale 3D printing. [4]在此基础上,PVA/Gd2O3:Eu3+ (5mol %)@BSA溶液对潜在指纹的掩蔽产生了柔性透明薄膜;在胶片上开发出具有明确脊线特征的高度稳定的指纹图像,从而实现个性化。 [1] 柔性透明薄膜加热器 (FTH) 用于各种应用,包括智能窗户和可穿戴设备,因为它们在产生焦耳热的同时对可见光透明。 [2] nan [3] nan [4]
flexible transparent conductor 柔性透明导体
In the final section, we evaluate three applications of flexible transparent conductors in: perovskite-based solar cells, organic light emitting diodes and electrochromic windows. [1] However, pristine graphene sheets are not suitable as flexible transparent conductors and many more applications due to the presence of defects, agglomeration behavior, and grain boundaries, while having high sheet resistance which can be broken easily and facing objection for designing controlled functionality. [2] One key obstacle in fabricating efficient flexible and printable optoelectronic devices is the absence of ideal flexible transparent conductors with superior optical, electrical, and mechanical properties. [3] 8 Ω/sq, indicating a big potential for application in flexible transparent conductors. [4]在最后一部分中,我们评估了柔性透明导体在钙钛矿基太阳能电池、有机发光二极管和电致变色窗中的三种应用。 [1] 然而,由于存在缺陷、团聚行为和晶界,原始石墨烯片不适合作为柔性透明导体和更多应用,同时具有高薄层电阻,容易断裂并且在设计受控功能方面面临反对意见。 [2] nan [3] nan [4]
flexible transparent thin
67 at%Cr/Zn–SnOx multilayer thin film with reliable and reversible heating performance as a flexible transparent thin film heater was fabricated. [1] A flexible transparent thin film was developed by embedding complex 1 into poly(urethane) (PU) polymer. [2]制备了具有可靠和可逆加热性能的 67 at%Cr/Zn-SnOx 多层薄膜作为柔性透明薄膜加热器。 [1] nan [2]
flexible transparent substrate
Flexible transparent substrate materials, which was able to withstand high dynamic strain, in contrast to traditional substrate materials. [1] Solution-processed metal oxides have been investigated as an alternative to vacuum-based oxides to implement low-cost, high-performance electronic devices on flexible transparent substrates. [2]与传统基板材料相比,柔性透明基板材料能够承受高动态应变。 [1] nan [2]
flexible transparent supercapacitor
PEDOT:PSS-glued MoO3 nanowires were anchored on AgNFs network to build all-solid-state flexible transparent supercapacitors with high performances. [1] Hierarchically ordered structures with low tortuosity, excellent mechanical flexibility, high optical transparency, and outstanding electrical conductivity are critically important in developing flexible transparent supercapacitor electrodes for innovative applications in electronics and displays. [2]PEDOT:PSS胶合MoO3纳米线锚定在AgNFs网络上,构建高性能全固态柔性透明超级电容器。 [1] nan [2]
flexible transparent wood
Herein, inspired by a bioluminescent noctiluca, a wood-based e-skin with instrument- and naked eye-readable characteristics was sandwich assembled using silver nanowires and a super-flexible transparent wood (STW) film as an electrode and a pyramidal microstructure polydimethlysiloxane film as a stimuli-responsive layer. [1] The present work, describes a ‘green’ method to fabricate a biodegradable and highly flexible transparent wood-polymer composite from poplar wood veneers and polyvinyl alcohol (PVA). [2]在此,受生物发光夜光虫的启发,使用银纳米线和超柔韧透明木材 (STW) 薄膜作为电极和金字塔形微结构聚二甲基硅氧烷薄膜夹层组装了具有仪器和肉眼可读特性的木质电子皮肤作为刺激反应层。 [1] nan [2]
flexible transparent electromagnetic 柔性透明电磁
Silver nanowire (Ag NW) has been considered as the best material to replace indium tin oxide (ITO) to fabricate flexible transparent electromagnetic interference (EMI) shielding films due to its superior comprehensive performance. [1] Flexible transparent electromagnetic interference (EMI) shielding materials in visual windows are essential for the innovation of optoelectronic devices. [2]银纳米线 (Ag NW) 因其优越的综合性能被认为是替代氧化铟锡 (ITO) 制备柔性透明电磁干扰 (EMI) 屏蔽膜的最佳材料。 [1] 可视窗中的柔性透明电磁干扰(EMI)屏蔽材料对于光电器件的创新至关重要。 [2]