导电高分子PEDOT/PSS保护银纳米颗粒的制备与表征

利用导电高分子聚(3,4-二氧乙基噻吩)/聚(对苯乙烯磺酸)(PEDOT/PSS)作保护剂,制备了银纳米颗粒,用UV-Vis和TEM对其进行了表征.结果表明,选择合适量的PEDOT/PSS保护剂可以得到大小分布较窄银纳米颗粒.     

乙撑二氧噻吩在中性水溶液中的电化学聚合及行为研究

本文研究了乙撑二氧噻吩在中性水溶液中的电化学聚合过程以及聚乙撑二氧噻吩膜的电化学行为, 利用光电子能谱和红外光谱等方法对聚合物膜进行了表征, 研究表明在中性水溶液中制成的聚乙撑二氧噻吩膜修饰电极具有较好的电化学行为和稳定性。     

PEDOT的固相聚合法制备及其在紫外光探测器中的应用

首先以2,5-二溴-3,4-乙撑二氧噻吩（DBEDOT）为单体，通过固相聚合法在掺杂氟的二氧化锡导电玻璃（FTO）基底表面制备聚（3,4-乙撑二氧噻吩）（PEDOT）膜，然后将其与氧化锌纳米阵列（ZnO NRs）修饰的FTO组装成有机-无机异质结紫外光探测器，并研究其紫外光探测性能。采用紫外-可见分光光谱（UV-Vis）、傅里叶变换红外光谱（FT-IR）、扫描电子显微镜（SEM）、X射线衍射光谱（XRD）等测试方法对材料进行表征。结果表明，固相聚合法制备的PEDOT能有效提升ZnO NRs基紫外光探测器的性能。器件在紫外光照射下（365 nm,0.32 mW/cm2）表现出较高响应度（15.34 mA/W）、较短响应时间（上升时间为0.159 s，下降时间为0.162 s）和较好的稳定性。     

一维轴向有机无机异质结肖特基二极管的制备及性能研究

一维有机无机杂化材料的制备一直以来是难点问题, 其不同组分间协同产生的新颖性能及广泛应用前景, 使其成为近年来研究热点. 通过多孔氧化铝模板辅助分步电化学沉积方法, 成功设计和制备了有机导电聚合物聚3,4-乙撑二氧噻吩[poly(3,4-ethylenedioxythiophene), PEDOT]和无机金属银(Ag)的分段式纳米线. 使用扫描电子显微镜(SEM)和透射电子显微镜(TEM)对其形貌和结构进行了表征. 采用顶端接触上电极的方式, 研究了单根PEDOT纳米线和单根PEDOT-Ag异质结纳米线的伏安特性曲线. 结果表明, 单根异质结纳米线展现出肖特基二极管行为, 正向开启电压为0.3 V, 反向击穿电压为1.5 V, 正向开启后电流达到微安数量级.     

纳米纤维素/聚3,4-乙撑二氧噻吩复合薄膜的制备及电致变色性能

以棉浆粕为原料,采用硫酸溶胀结合超声波处理的方法制备了纳米纤维素(NC).在纳米纤维素的水分散液中加入3,4-乙撑二氧噻吩单体,以过硫酸铵为氧化剂,采用原位化学氧化法制得了纳米纤维素/聚3,4-乙撑二氧噻吩(NC/PEDOT)纳米复合物.对NC和NC/PEDOT复合物进行扫描电镜、透射电镜和红外光谱分析.将纳米复合物的水分散液滴涂在氧化铟锡(ITO)玻璃表面形成复合薄膜,考察不同纳米纤维素含量对NC/PEDOT复合薄膜电致变色性能的影响.结果表明,NC呈棒状,平均直径为20 nm,长度为100~300nm;NC/PEDOT复合物中PEDOT均匀包覆在NC表面形成核壳结构,平均直径为30 nm;复合薄膜中当NC含量为60%时,其电致变色性能最好,具有最高的对比度(24.4%),最短的响应时间(1 s),最高的着色效率(51.8 cm~2/C).     

聚(3,4-乙撑二氧噻吩)/木质素磺酸导电复合物的结构与性能

3,4-乙撑二氧噻吩(EDOT)以木质素磺酸(LS)作载体,通过化学氧化法聚合形成了聚(3,4-乙撑二氧噻吩)/木质素磺酸(PEDOT/LS)导电复合物.该导电复合物的结构与性能分别采用紫外可见分光光度计、红外光谱仪、zeta电位及粒度分析仪、原子力显微镜、X-射线光电子能谱仪、X-射线衍射仪、四探针测试仪、电泳仪,以及表面电阻仪来表征.结果表明,EDOT能在LS水溶液中氧化聚合,得到水分散性PEDOT/LS导电颗粒.该颗粒是一种聚电解质复合物,等量电荷配比的PEDOT/LS位于内核而富余的亲水性LS包在外层.LS与PEDOT两者之间存在较强的作用力,无法通过电泳分开.X-射线衍射仪结果表明该复合物是无定型的.当LS与EDOT单体质量比从0.7∶1升高至3.0∶1时,复合物的粒径从673 nm降低至348 nm,涂膜表面变得均匀,同时表面电阻从1.9 kΩ/sq上升至87.2 kΩ/sq.用PEDOT/LS配置得到的抗静电剂,可以使玻璃片表面电阻从1012Ω/sq减小至107Ω/sq.     

聚(2-甲氧基-5-乙氧基苯)撑纳米阵列的形态和光学特性

在阳极氧化铝(AAO)模板的纳米孑L内通过1—甲氧基—4—乙氧基苯(MEB)的氧化偶合聚合组装聚(2—甲氧基—5—乙氧基苯)撑(MEO—PPP)纳米纤维阵列，通过对纳米线的分子结构，AAO模板和聚(2—甲氧基—5—乙氧基苯)撑纳米纤维阵列的形态和形貌表征表明，AAO模板的纳米孔均匀有序且相互平行，定向生长的聚(2—甲氧基—5—乙氧基苯)撑纳米纤维的分子链与AAO纳米孔的轴线平行，聚合物分子链的定向排列能够显著提高电导率，MEO—PPP分子链的聚对苯撑(PPP)骨架有良好的π-π^*共轭体系，引起吸收带向长波方向移动，MEO—PPP纳米纤维阵列比其无序纳米纤维有5nm的发射蓝移。     

用CdSe/ZnS量子点提高体异质结有机太阳电池的效率

通过掺杂吸收光谱在可见光波段的量子点可提高聚合物对可见光的吸收,因此掺杂CdSe/ZnS核-壳结构量子点(CQDs)能提高聚(3-己基噻吩):[6,6]-苯基-C61-丁酸甲酯(P3HT:PCBM)体异质结太阳电池的能量转换效率.本文研究了CdSe/ZnS量子点在P3HT:PCBM中的不同掺杂比例及其表面配体对太阳电池光伏性能的影响,优化器件ITO(氧化铟锡)/PEDOT:PSS(聚(3,4-乙撑二氧噻吩:聚苯乙烯磺酸)/P3HT:PCBM:(CdSe/ZnS)/Al的能量转换效率达到了3.99%,与相同条件下没有掺杂量子点的参考器件ITO/PEDOT:PSS/P3HT:PCBM/Al相比,其能量转换效率提高了45.1%.     

含3,4-乙撑二氧取代基的聚三噻吩衍生物的合成与表征

通过Stille反应合成了3,′4′-乙撑二-氧2,2′∶5,′2″-三噻吩,并以其作为单体,在0~5℃下,以FeCl3为氧化剂,在氯仿溶液中合成了3种聚(3,′4′-乙撑二氧-2,2′∶5,′2″-三噻吩)。并采用紫外-可见光谱(UV-Vis)、傅里叶红外光谱(FT-IR)、凝胶色谱(GPC)、循环伏安(CV)、透射电镜(TEM)和热重分析(TGA)对聚合物进行了表征。同时讨论了乙撑二氧取代基和FeCl3用量对聚合物性质的影响。结果表明:聚合物的紫外最大吸收为466~474 nm,数均分子量为3.4×103~3.6×103,能隙大约为2.05 eV,热分解温度为110℃。     

硅纳米线阵列的制备及其光电应用

近年来,硅纳米线阵列在宽波段、宽入射角范围内优异的减反射性能及其在光电领域的巨大应用前景引起了相关研究者的广泛关注。本文综述了国内外硅纳米线阵列的制备及其在光电应用方面的最新研究进展。关于硅纳米线阵列的制备方法,主要从"自下而上"和"自上而下"两大类出发,分别阐述了模板辅助的化学气相沉积法、化学气相沉积结合Langmuir-Blodgett技术法和金属催化化学刻蚀法,其中重点介绍了目前使用最为广泛且操作简单的金属催化化学刻蚀法的步骤、机理及控制参数。关于硅纳米线阵列在光电领域的应用,主要阐述了硅纳米线阵列在光电探测器、常规太阳能电池、光电化学太阳能电池、光催化分解水制氢、光催化降解有机污染物方面的应用。最后,从硅纳米线阵列在实际应用中面临的提高光电转换效率和避免硅纳米线阵列腐蚀以提高器件的稳定性等问题出发,展望了硅纳米线阵列的表面修饰及修饰后的性能研究是未来硅纳米线阵列光电应用研究的主要方向之一。     

Nanoplasmonic zirconium nitride photocatalyst for direct overall water splitting

The ability of plasmonic nanostructures to efficiently harvest light energy and generate energetic hot carriers makes them promising materials for utilization in photocatalytic water spitting.Apart from the traditional Au and Ag based plasmonic photocatalysts,more recently the noble-metal-free alternative plasmonic materials have attracted ever-increasing interest.Here we report the first use of plasmonic zirconium nitride（ZrN） nanoparticles as a promising photocatalyst for water splitting.Highl...     

A plasmonic photocatalyst consisting of silver nanoparticles embedded in titanium dioxide

Titanium dioxide (TiO2) displays photocatalytic behavior under near-ultraviolet (UV) illumination. In another scientific field, it is well understood that the excitation of localized plasmon polaritons on the surface of silver (Ag) nanoparticles (NPs) causes a tremendous increase of the near-field amplitude at well-defined wavelengths in the near UV. The exact resonance wavelength depends on the shape and the dielectric environment of the NPs. We expected that the photocatalytic behavior of TiO2 would be greatly boosted if it gets assisted by the enhanced near-field amplitudes of localized surface plasmon (LSP). Here we show that this is true indeed. We named this new phenomenon "plasmonic photocatalysis". The key to enable plasmonic photocatalysis is to deposit TiO2 on a NP comprising an Ag core covered with a silica (SiO2) shell to prevent oxidation of Ag by direct contact with TiO2. The most appropriate diameter for Ag NPs and thickness for the SiO2 shell giving rise to LSP in the near UV were estimated from Mie scattering theory. Upon implementing a device that took these design considerations into account, the measured photocatalytic activity under near UV illumination of such a plasmonic photocatalyst, monitored by decomposition of methylene blue, was enhanced by a factor of 7. The enhancement of the photocatalytic activity increases with a decreased thickness of the SiO2 shell. The plasmonic photocatalysis will be of use as a high performance photocatalyst in nearly all current applications but will be of particular importance for applications in locations of minimal light exposure.     

Exploration of silver decoration concentration to enhance photocatalytic efficiency of titanium dioxide photocatalysts

Ag decoration on TiO₂ is favorable to absorption of visible light and wider absorption range. Ag nanoparticles playing the role of electron receivers on TiO₂ surface enhance photodegradation. However, excess Ag nanoparticles caused reduced specific surface area of photocatalysts and increased probability of charge recombination, resulting in lower photocatalytic efficiency. In this study, the influence of various Ag decoration concentrations on photocatalytic activity was investigated. Surface treatment by nitric acid after Ag decoration was performed to avoid excessive Ag deposition. The extent of Ag elimination and its impacts on photocatalytic activity were also explored. An optimum Ag content in the photocatalyst was achieved and photocatalytic efficiency was obviously improved. It was found that the number of calcination times affected the crystallinity and stability of photocatalysts. Better photocatalytic efficiency could be obtained after twice calcinations.     

The dependence of photocatalytic activity and photoinduced self-stability of photosensitive AgI nanoparticles

AgI is instable under light irradiation owing to its photosensitive properties, while a supported Ag-AgI composite has been demonstrated to be a stable photocatalyst. However, seldom investigations have been focused on the photocatalytic activity (including deactivation) and photoinduced stability of the photosensitive AgI materials. In this study, the AgI nanoparticles were immobilized on the surface of Ag(8)W(4)O(16) nanorods by an anion-exchange route and their photocatalytic activities were evaluated by photocatalytic decomposition of methyl orange and phenol solutions under visible-light irradiation. A photoinduced self-stabilizing mechanism of the AgI nanoparticles was proposed to account for the formation of a stable Ag-AgI photocatalyst, namely, instable AgI can transform into a stable Ag-AgI photocatalyst after in situ formation of partial Ag on the surface of AgI nanoparticles. The photocatalytic performance of the immobilized AgI photocatalyst was greatly influenced by the formation of metallic Ag. With increasing repetitions of photocatalytic experiments, the initial deactivation was accompanied by the rapid increase of metallic Ag owing to the reduction of lattice Ag(+), while the subsequently stable activity corresponds to the formation of a stable Ag-AgI composite photocatalyst. Compared with the un-immobilized AgI photocatalyst, the immobilized AgI nanoparticles exhibited a higher and more stable photocatalytic performance.     

新型等离子光催化剂纳米金-钛酸锌复合物的制备与光解水制氢性能

利用溶胶-凝胶法及光沉积法制备纳米金-钛酸锌(Nano Au-ZnTiO₃)复合等离子光催化剂。 采用X射线衍射(XRD)、场发射扫描电子显微镜(FE-SEM)、紫外可见漫反射光谱、荧光光谱、光电流密度、光催化制氢性能等技术手段和测试表征了样品的结构及性能。 结果表明,ZnTiO₃在900 ℃煅烧下呈立方相和六角相的混合相,其形貌呈近似球形,粒径约为50~100 nm。 由于纳米金(Nano Au)的表面等离子共振效应,Nano Au-ZnTiO₃复合材料在可见光区有较强的吸收,吸收峰位于525 nm处。 Nano Au-ZnTiO₃复合等离子光催化剂在可见光激发下呈现出优良的光催化分解水制氢活性。     

Preparation of Cu nanoparticle‐doped ZIF‐8/RGO composites for effective photodegradation of organic pollutant

Cu nanoparticle‐connected ZIF‐8/reduced graphite oxide (RGO) composite was successfully prepared through a facile hydrothermal reaction using sulfate in this paper. The crossover mechanism of metal nanoparticles loading and RGO decoration to enhance the photocatalytic efficiency of pristine ZIF‐8 was studied. The results showed that the prepared Cu‐S@ZIF‐8/RGO has a strong ability to take advantage of sunlight, indicating an appreciable application prospect. RGO can act as a base to support the whole structure and serve as an electron sink to accept photoexcited electrons, realizing the formation of reactive oxygen species (ROS) and inhibition of electron–hole pair recombination. Cu nanoparticles act as connectors between ZIF‐8 and RGO to transfer electrons and realize the formation of partial ROS on its surface. The doped sulfate radical can promote to extend the utilization of the wavelength range by generating surface states. Cu‐S@ZIF‐8/RGO showed the best photocatalytic activity in simulated sunlight for eliminating rhodamine B and 4‐chlorophenol among all the prepared samples, the structure kept intact even in the presence of different kinds of anions. The crossover study of metal loading and RGO decoration can develop a new way for only UV‐responsive metal–organic frameworks to remove organic contaminants under sunlight irradiation.     

可见光驱动Au/SrTiO3纳米等离子体光催化剂分解水制氢

采用水热法和光沉积法制备了Au/SrTiO_3纳米等离子体光催化剂。通过XRD、XPS、SEM、TEM、EDS和DRS等技术对光催化剂的结构、组成、形貌、粒子大小和光吸收性质等进行了表征,考察了Au/SrTiO_3纳米光催化剂在可见光照下的制氢性能。结果表明,采用水热法成功合成了SrTiO_3纳米粒子,通过负载Au纳米粒子后,由于表面等离子体共振效应,增强了其对可见光的吸收。此外,测试了不同Au负载量对SrTiO_3光催化剂在可见光照下制氢活性的影响,其中,5%Au/SrTiO_3光催化剂在可见光照下制氢活性最高,并对其光催化反应机理进行了进一步的探讨。     

Highly Efficient Visible Light Plasmonic Photocatalyst Ag@Ag(Br,I)

The new plasmonic photocatalyst Ag@Ag(Br,I) was synthesized by the ion‐exchange process between the silver bromide and potassium iodide, then by reducing some Ag⁺ ions in the surface region of Ag(Br,I) particles to Ag⁰ species. Ag nanoparticles are formed from Ag(Br,I) by the light‐induced chemical reduction reaction. The Ag@Ag(Br,I) particles have irregular shapes with their sizes varying from 83 nm to 1 μm. The as‐grown plasmonic photocatalyst shows strong absorption in the visible light region because of the plasmon resonance of Ag nanoparticles. The ability of this compound to reduce Cr^VI under visible light was compared with those of other reference photocatalyst. The plasmonic photocatalyst is shown to be highly efficient under visible light. The stability of the photocatalyst was examined by X‐ray diffraction and X‐ray photoelectron spectroscopy. The XRD pattern and XPS spectra prove the stability of the plasmonic photocatalyst Ag@Ag(Br,I).     

双功能S-型g-C3N4/Bi/BiVO4复合光催化剂驱动人工碳循环（英文）

长期以来,陆地、大气和海洋之间的碳循环维持了大自然碳平衡.随着密集人类活动和高度工业发展,碳燃料、碳化学品和碳材料广泛应用于各个领域,导致碳排放过量,碳平衡已被严重破坏,碳污染已成为一个严峻问题.例如,持久性有机污染物和挥发性有机化合物过量排放到环境中,威胁着人类的健康和生态平衡.人们陆续开发出各种先进的环境技术,如微生物分解,去除空气和水中的碳基污染物,将有毒有害的有机化合物转化为无害CO2.但是,CO2本身是大气中的主要温室气体,它在大气中的浓度早超过了天然碳循环所能维持的环境自洁净能力.基于先进催化技术建立人工碳循环,将有机污染物矿化生成的CO2进一步转化为有价值的有机化学品(如太阳能燃料)是一种理想的低碳方法.光合作用是自然碳循环中核心过程之一,是降低大气中CO2浓度的关键.受到光合作用启发,科学家们积极开发人工光合成技术推动CO2资源化.人工光合成技术本质上基于半导体光催化过程.半导体光催化过程具有双重作用.一方面,基于有氧光催化氧化过程,有机污染物可以矿化生成无毒CO2.另一方面,基于缺氧光催化还原过程,CO2可以转化为碳氢化合物太阳能燃料.理论上,结合上述两个过程,为建立人工碳循环奠定基础,但是,至今很少有人成功建立有氧氧化-无氧还原串联光催化工艺,实现人工碳循环.难点在于有机污染物的有氧氧化反应和CO2的无氧还原反应的操作条件与反应机制是完全不同的,目前缺乏同时适用于上述两种反应的双功能光催化剂.本文成功构建了具有双功能的g-C3N4/Bi/BiVO4三元复合光催化剂,它不仅在降解有机污染物方面表现出优异的有氧光催化氧化性能(以降解染料罗丹明B为例),而且还表现出优异的缺氧CO2光催化还原性能.此外,基于“一锅法”厌氧耦合氧化-还原反应,g-C3N4/Bi/BiVO4三元复合光催化剂成功实现同步罗丹明B降解与太阳能燃料生成,构建了从毒害有机污染物到高品质太阳燃料的碳循环.结合牺牲剂实验分析与密度泛函理论理论计算,作者提出g-C3N4/Bi/BiVO4复合光催化剂的双功能性与g-C3N4与BiVO4界面内建S-型复合异质结有关.S-型复合异质结既促进界面电荷转移与分离,又维持了最佳电荷氧化还原电位.此外,S型g-C3N4/Bi/BiVO4复合光催化剂中原位生成的具有等离子体效应的Bi纳米颗粒具有双重作用,既促进界面电荷定向转移,又促进可见光吸收.本文开发的新型双功能S-型g-C3N4/Bi/BiVO4复合光催化剂系统为进一步开发集成式有氧-缺氧光催化碳循环反应系统奠定基础.     

Nanostructured materials with localized surface plasmon resonance for photocatalysis

Localized surface plasmon resonance（LSPR） enhanced photocatalysis has fascinated much interest and considerable efforts have been devoted toward the development of plasmonic photocatalysts.In the past decades,noble metal nanoparticles（Au and Ag） with LSPR feature have found wide applications in solar energy conversion.Numerous metal-based photocatalysts have been proposed including metal/semiconductor heterostructures and plasmonic bimetallic or multimetallic nanostructures.However,high cost and...