MoO_3电致变色薄膜的XPS研究

近年来 ,随着人们提倡节能和使用洁净能源 ,无机电致变色材料在建筑物采光控制系统和反射率可调表面的应用研究 ,已成为材料领域的一个新热点 .WO3、 MoO3等过渡金属氧化物薄膜具有良好的电致变色效应 ,是人们研究的重点 .其中 MoO3的电致变色效果要好于 IrO2、 TiOx、 CoO及 NiOx等电致变色材料 [1],而且它在可见光区有比 WO3更柔和的色彩 ,使人眼更易于适应其颜色变化 .着色态的 MoO3称为钼青铜 ,其开路记忆也好于钨青铜 [2].故 MoO3电致变色薄膜是极有潜力用于实用化的电致变色器件 .MoO3薄膜常用的制备方法有真空蒸 发、化学气…     

磷腈-紫精聚合物的合成与电致变色性能

以六氯环三磷腈作为核心、 紫精为电致变色活性基, 合成了一种新型有机-无机杂化电致变色材料——六(1-乙基-4,4'-联吡啶-甲基苯氧基)环三磷腈(PHV ²⁺). 通过傅里叶变换红外光谱(FTIR)、 X射线衍射(XRD)及核磁共振氢谱( ¹H NMR)表征了PHV ²⁺的结构. 优良的水溶性使得该化合物可以通过简单的方法构造一个以聚乙烯醇(PVA)为凝胶基质的电致变色水凝胶, 具有成本低廉及无毒害的优点. 以氟掺杂氧化锡(FTO)涂层玻璃作为电极材料, PHV ²⁺作为电致变色材料制备了PHV ²⁺/PVA/KCl电致变色器件(PHV ²⁺/PVA/KCl ECD). 该电致变色器件在2.1 V电压下由淡黄色变为紫色, 颜色变化明显, 并且该颜色变化可以循环500次; 器件在526 nm处的光学对比度达到62.19%. 良好的电致变色性质使该化合物在电致变色器件方面具有潜在应用价值.     

氧化铑变色薄膜的制备及其电变色研究

采用溶胶-凝胶方法制备了氧化铑电致变色薄膜。通过施加阴极或阳极电位, 薄膜在碱性电解液中呈现从亮黄（还原态）到深绿（氧化态）的可塑颜色变化,而 且可达到上千次循环而性能不变。采用XRD,SEM,TG,DTA,UVV,FTIR和循环伏安 等技术对薄膜的晶态、形貌、热处理过程和电变色过程进行了研究。得出100 ℃处 理的膜内含有一定量的结晶水,其性能最好。对薄膜的电致变色性能如：着色效率 、响应时间及循环寿命、开路记忆等进行了测试,并讨论了氧化铑薄膜电变色的反 应机理。     

苯胺四聚体合成及电致变色器件制备——一个大学化学综合性实验

介绍一个研究探索型大学化学综合性实验——苯胺四聚体合成及其电致变色器件制备。内容包括苯胺四聚体的合成及简单的电致变色器件的制备和相关性能的测试。通过本实验的实践,可以让学生拓宽相关化学专业知识,提高学生综合实验操作技能和专业素质,让学生接触所学领域的前沿技术,激发学生对科学研究的兴趣,培养科研探究能力。     

紫精-普鲁士蓝凝胶电致变色器件的制备

合成了醛基功能化的紫精,1,1′-二醛己基-4,4′-联吡啶,通过与聚乙烯醇的缩醛反应将紫精固定到凝胶电解质中,对电极用电沉积法沉积普鲁士蓝,制备了新型凝胶型电致变色器件。这种凝胶电致变色器件避免了电解质泄露的风险并拓宽了电致变色器件的应用范围。采用1 HNMR对分子结构进行了表征,通过紫外-可见分光光度计研究了器件的电致变色性能及其影响因素。结果表明:采用将紫精通过共价键并入凝胶的方法,制备的器件在±2V的工作电压下具有47%的对比度,着色时间2.8s,褪色时间3.3s,并且具有良好的循环稳定性。     

基于原位聚合离子液体凝胶的固态电致变色器件的制备及性能研究

本文通过在离子液体BmimPF6中原位热聚合甲基丙烯酸甲酯得到了透明的离子液体凝胶。通过交流阻抗测定,当BmimPF6与甲基丙烯酸甲酯的质量比为5∶1时,离子液体凝胶的导电率为1.33×10-3Scm-1。将通过电化学沉积制得的三氧化钨(WO3)和普鲁士蓝(PB)修饰FTO电极,与上述离子液体凝胶一起组装得到了全固态的电致变色器件。原位吸收光谱数据显示所制得的电致变色器件,在±2V的工作电压下,具有稳定的电致变色响应,其着色和褪色时间分别为4.5s和4.0s,着色效率达190cm2C-1(λ=660nm)。     

基于无机电致变色材料的变色储能器件

电致变色和电化学储能的原理均是基于电荷在电极中的嵌入或脱出而发生的氧化还原反应,具有相同的电化学本质。将电致变色和电化学储能功能集成在一起的电化学器件即电致变色储能器件。以锂离子电池为代表的电化学储能器件已广泛商业化,单一功能的电致变色器件也已被广泛报道并有商业化应用,但有关电致变色储能器件的研究仍然停留在实验阶段。该类器件在电化学储能的同时,可以改变其在可见光甚至红外波段的透射率,并可用颜色指示器件的荷电状态,为电化学器件提供新的应用前景。电致变色储能器件主要包括电致变色超级电容器、电致变色电池和光驱动电致变色智能窗等。电致变色超级电容器和电致变色电池以同时具有电致变色效应和电荷存储性质的材料为正负电极,光驱动电致变色智能窗则还包括将光能转化为电能的光电转换部分。这些器件可用于建筑节能智能窗、静态显示、智能传感等。此外,在柔性基底上制备的可穿戴电致变色储能器件在智能服装、植入显示器和电子皮肤等方面具有应用潜力。本文从基本原理、研究进展和应用领域等方面对无机电致变色储能材料与器件进行综述,并提出未来的研究展望。     

金属-超分子聚合物的合成及其多色电致变色器件

本文合成了一种多齿配体化合物——1,4-双(2,2′:6′,2′′-三联吡啶-4′-基)苯及其Fe/Ru金属-超分子聚合物——Poly Fe和Poly Ru,同时以喷涂在ITO导电玻璃上的Fe/Ru金属-超分子聚合物膜为工作电极、0.1 mol/L Li Cl O4水溶液为电解质,并添加K_3Fe(CN)_6为电化学互补材料,制作了系列电致变色器件.由Poly Fe和Poly Ru的组合,可以得到从Poly Fe的蓝紫色渐变到Poly Ru橙红色的彩色薄膜及其多色电致变色器件,器件响应速度快(2 s),褪色电压0.9~1.2 V,着色电压0 V,最大光学对比度约57%.添加K_3Fe(CN)_6后,器件的寿命得到极大提高.     

固态聚苯胺电致变色器件的制备和性能

采用CeO2-TiO2复合物薄膜作为聚苯胺电致变色器件的对电极, 选用聚合物固态电解质(PE: PMMA-PC-EC-LiClO4), 构筑了新型双层结构(Dual-type)聚苯胺(PANI)固态电致变色(EC)器件. 用电化学现场紫外-可见光谱法表征了该EC器件(ITO|PANI||PE||CeO2-TiO2|ITO)的电致变色性能, 并与单层结构(Single-type)EC器件(ITO|PANI||PE|| ITO)进行了比较. 研究结果表明, 双层结构EC器件比单层结构EC器件的电致变色性能好, 如响应速度快, 循环寿命长. 同时, 考察了电解质组分对聚苯胺电致变色稳定性的影响. EC器件(ITO|PANI||PE||CeO2-TiO2|ITO)的颜色呈现由透明的黄色(-1.5 V, PANI vs. CeO2-TiO2)到蓝色(1.0 V)的可逆变化, 在700 nm处的透射率由42.19%变到13.35%, 经过150个循环, 其透射率差仍保持不变, 着色效率为152.1 cm2/C.     

可吸附紫精化合物电致变色器件

研究报道了一种基于可吸附的固态紫精化合物电致变色器件. 我们设计并合成了一种新型可吸附的不对称紫精化合物,其一端引入三苯胺基团用以修饰紫精化合物的电致变色性质,另一端引入膦酸基团使其固定于电极上,以提高变色速度,增加器件稳定性. 将所合成的材料应用于器件中,得到了高透过差值和高稳定的电致变色器件. 我们利用紫外-可见-红外分光光度计、电化学工作站以及CIE 1931 %Y_Lxy色度系统对其电致变色性能以及颜色进行了表征.     

The Synthesis of l-Ethyl-1''''-(4-vinylbenzyl)-4, 4''''-bipyridinium Chloride and Iodide and its Electrochromic Property

A new compound 1-ethyl-1'-(4-vinylbenzyl)-4, 4'-bipyridinium chloride and iodide has been synthesized. The cyclic voltammogram and impedance spectra indicated that a layer of viologen's electrochromic (EC) film could be deposited on conductive ITO glass working electrode. With polyelectrolyte as ionic conduction layer, solid EC devices based on this compound have been assembled and their thickness was about 2.35 mm. When different voltages were added, they showed blue or violet red color. After optimization, its response time was less than 50 ms, the number of redox circulation was over 107 and the color of coloration states could be kept for 3 days. This kind of EC device can meet the demand of electronic ink.     

可控变色织物制备及颜色控制研究

基于聚苯胺电致变色高聚物、采用反射型电致变色器件结构模型,以柔性导电织物作为电极,构建了可控变色织物,可在-1.0～+1.0 V低电压范围内实现颜色变化显著的黄色和绿色的可逆响应.系统研究了变色织物在不同电压、不同弛豫时间及不同颜色工作电极下的L*a*b*,ΔE*值及反射率曲线,且讨论了透射型电致变色器件和电致变色织物的区别.随着正电压的增加,变色织物对应的a*b*依次减小,蓝绿色加深;随着负电压的增加,变色织物对应的a*b*依次增加,变色织物黄色加深.撤去电压后变色织物发生放电弛豫,慢慢回复到未加电压时的本征态.工作电极底色对电致变色织物也有显著的影响.变色织物的断电放电弛豫时间低于透射型电致变色器件.     

Effects of Supporting Electrolytes on Spectroelectrochemical and Electrochromic Properties of Polyaniline‐poly(styrene sulfonic acid) and Poly(ethylenedioxythiophene)‐poly(styrene sulfonic acid)‐based Electrochromic Device

Electrochromic devices are fabricated by using polyaniline (PANI) doped with poly(styrene sulfonic acid) (PSS) as coloring electrodes, poly(ethylenedioxythiophene)‐poly(styrene sulfonic acid) (PEDOT‐PSS) as complementary electrodes, and hybrid polymer electrolytes as gel electrolytes. The device based on LiClO₄‐based electrolyte (weight ratio of PMMA:PC:LiClO₄ = 0.7:1.1:0.3) shows the highest optical contrast and coloration efficiency (333 cm²/C) after 1200 cycles in these devices, and the color changes from pale yellow (?0.5 V) to dark blue (+2.5 V). The spectroelectrochemical and electrochromic switching properties of electrochromic devices are investigated, the maximum optical contrast (ΔT%) of electrochromic device for ITO|PANI‐PSS‖PMMA‐PC‐LiClO₄‐SiO₂‖PEDOT‐PSS|ITO are 31.5% at 640 nm, and electrochromic device based on LiClO₄‐based electrolyte with SiO₂ shows faster response time than that based on LiClO₄‐based electrolyte without SiO₂.     

Comparative study of optical kinetics in single and dual poly3-methylthiophene-based solid electrochromic devices

An electrochemically deposited poly3-methylthiophene (P3MT) thin film has been used as the primary electrochromic element in a solid two-electrode electrochromic device (ECD) with a viscous polymeric electrolyte (PE) of polymethyl methacrylate and lithium perchlorate co-dissolved in ethylene and propylene carbonates. The counter-electrode of the ECD was a transparent conductive (indium-tin oxide, ITO) glass (single ECD) or a polyaniline (PANI)-coated ITO glass (dual ECD). Dual P3MT-PANI-based ECDs exhibit a lower optical switch potential (less than 0.5 V) and a faster color change speed (around 1 s) compared with the single devices, independent on the lithium salt concentration and the viscosity of the polymeric electrolyte. Electrochemical impedance spectra of both types of ECDs were analyzed at zero bias. It indicates that the use of the secondary electroactive element leads to a lower counter-ion diffusion resistance as well as to a larger counter-ion storage capacity in the electrochromic element/polymeric electrolyte interfaces. Consequently, the oxidation–reduction potential is lower, and the charge transfer process is faster in the dual devices than those in the single ones.     

脉冲激光沉积制备氧化铋薄膜的电致变色性质

通过电位阶跃和循环伏安结合现场电感偶合分光光度计(CCD)测量了脉冲激光沉积的四方结构Bi2O3薄膜的电致变色性质. 结果表明, 在波长为630 nm处出现一个明显的吸收峰, Bi2O3薄膜电极的着色时间为30 s. 吸光度-电位谱图表明, 当电位在3.5 - 0.7 V之间变化时, Bi2O3薄膜的颜色可明显地呈现由透明到暗棕色的可逆变化, 重复次数可达50 次, 在630 nm测得的着色效率约为15 cm2·C-1.     

Tuneable Redox Chemistry and Electrochromism of Persistent Symmetric and Asymmetric Azine Radical Cations

Molecular organic radicals have been intensively studied in the last decades, due to their interesting optical, magnetic and redox properties. Here we report the synthesis and characterisation of persistent organic radicals from one-electron oxidation of redox-active azines (RAAs), composed of two guanidinyl or related groups. By connecting two different groups together, asymmetric compounds result. In this way a series of compounds with varying redox potential is obtained that could be oxidised reversibly to the mono- and the dicationic charge states. The accessible redox states were fully determined by chemical redox reactions. The standard Gibbs free energy change for disproportionation of the radical monocation into the dication and the neutral molecule in solution, estimated from cyclovoltammetric measurements, varies between 43 and 71 kJ mol⁻¹. While the neutral RAAs absorb predominately UV light, the radical monocations display strong absorptions covering almost the entire visible region and extending for some compounds into the NIR region. A detailed analysis of this highly reversible electrochromism is presented, and the fast switching characteristics are demonstrated in an electrochromic test device.     

Two-dimensional Covalent Organic Frameworks for Electrochromic Switching

The electrochromic materials have received immense attention for the fabrication of smart optoelectronic devices. The alteration of the redox states of the electroactive functionalities results in the color change in response to electrochemical potential. Even though transition metal oxides, redox-active small organic molecules, conducting polymers, and metallopolymers are known for electrochromism, advanced materials demonstrating multicolor switching with fast response time and high durability are of increasing demand. Recently, two-dimensional covalent organic frameworks (2D COFs) have been demonstrated as electrochromic materials due to their tunable redox functionalities with highly ordered structure and large specific surface area facilitating fast ion transport. Herein, we have discussed the mechanistic insights of electrochromism in 2D COFs and their structure-property relationship in electrochromic performance. Furthermore, the state-of-the-art knowledge for developing the electrochromic 2D COFs and their potential application in next-generation display devices are highlighted.     

Electrochromic device based on carbon nanotubes functionalized poly (methyl pyrrole) synthesized in hydrophobic ionic liquid medium

A facile approach of carbon nanotubes (CNTs) functionalized poly(methylpyrrole) [pMPy] electrosynthesized in hydrophobic ionic liquid for fabrication of electrochromic (EC) devices is discussed. Clear change from brown (oxidized) to pale yellow (neutral) color is demonstrated with robust cycle life. This synthesis route can be exploited to fabricate polymers from other organic conjugated systems and provide an avenue for applications requiring stable redox polymers in electrochromic devices.     

Establishing dual electrogenerated chemiluminescence and multicolor electrochromism in functional ionic transition-metal complexes

A combination of electrochromism and electroluminescence in functional materials could lead to single-layer dual electrochromic/electroluminescent (EC/EL) display devices, capable of simultaneous operation in emissive and reflective modes. Whereas such next generation displays could provide optimal visibility in any ambient lighting situation, materials available that exhibit such characteristics in the active layer are limited due to the required intrinsic multifunctionality (i.e., redox activity, electroluminescence, electrochromism, and ion conductivity) and to date can only be achieved via the rational design of ionic transition-metal complexes. Reported herein is the synthesis and characterization of a new family of acrylate-containing ruthenium (tris)bipyridine-based coordination complexes with multifunctional characteristics. Potential use of the presented compounds in EC/EL devices is established, as they are applied as cross-linked electrochromic films and electrochemiluminescent layers in light-emitting electrochemical cell devices. Electrochromic switching of the polymeric networks between yellow, orange, green, brown and transmissive states is demonstrated, and electrochemiluminescent devices based on the complexes synthesized show red-orange to deep red emission with λ(max) ranging from 680 to 722 nm and luminance up to 135 cd/m(2). Additionally, a dual EC/EL device prototype is presented where light emission and multicolor electrochromism occur from the same pixel comprised of a single active layer, demonstrating a true combination of these properties in ionic transition-metal complexes.     

聚苯胺基反射型柔性电致变色器件的制备与工艺研究

采用化学法合成聚苯胺(PANI),在柔性不锈钢丝网上进行涂覆,成功制备了反射型柔性变色器件.测试并获取了不同电位下(即不同的掺杂态)的紫外-可见光全反射光谱,比较确定了该变色器件合适的使用电压为+0.7V和-0.6V.并在选定的使用电压下对变色器件进行测试,讨论了工作电极上PANI用量、电解质层用量和离子储存层用量对变...