InP-SiO2三维光子晶体的制备

用溶剂蒸发法将单分散SiO2微球组装成三维有序结构的胶体晶体,用金属有机化学气相沉积技术向SiO2胶体晶体中填充高折射率材料InP,获得了InP-SiO2两种介质复合的三维光子晶体,通过扫描电子显微镜、X射线衍射、能谱和紫外-可见光谱仪对InP-SiO2三维光子晶体的形貌、结构和光学性能进行了观察测试。研究结果表明：InP在SiO2微球空隙间具有较高的结晶质量,填充较致密均匀、与相同晶格周期的SiO2光子晶体相比,InP-SiO2光子晶体的反射光谱的峰值波长发生明显的红移。     

ZnS-opal与反opal结构ZnS光子晶体的组装

以单分散SiO2微球为基元,在75%～80%湿度、30～45 ℃恒温密闭烘箱中垂直快速组装opal模板;以Zn(NO3)2（0.035 mol/L）、TAA乙醇溶液（0.05 mol/L）为前体,通过溶剂热法充填形成ZnS-opal复合光子晶体;ZnS-opal复合光子晶体在2%～5%的HF溶液中浸泡4～5 h后卸载模板,制得反opal结构ZnS基光子晶体;采用XRD、SEM、ＵV-Vis测试手段对反opal结构ZnS基光子晶体形貌、物相和光学性能进行了表征。结果表明：溶剂热法多次充填可使ZnS纳米晶在模板密堆积形成的空隙中均匀成核;经过酸处理的ZnS-opal中SiO2微球溶解、坍塌,形成蜂窝状三维有序介孔和反opal结构ZnS基光子晶体;相同粒径SiO2微球组装的opal模板、ZnS-opal以及反opal结构ZnS光子晶体均表现出光子带隙特性,但反opal结构ZnS光子晶体带隙位置相比前两者发生了蓝移。     

有序大孔二氧化硅微球的制备研究

采用乳液聚合法合成了单分散改性聚苯乙烯（PS）乳胶粒,利用PS乳胶粒自组装制得胶体晶体（“蛋白石”）微球,通过溶胶-凝胶模板法制备了有序大孔SiO2（“反蛋白石”）微球,通过SEM对改性PS乳胶粒、胶体晶体微球和有序大孔SiO2微球表面形貌进行了表征。结果表明,改性PS乳胶粒呈单分散性,粒径为317 nm;胶体晶体微球表面PS乳胶粒排列有序;有序大孔SiO2微球表面呈有序多孔,其孔呈六边形,孔径分布均一,约为200 nm。     

TiO2反opal球形光子晶体颗粒的制备

联合萃取辅助微乳液法和液相沉积技术成功制备了TiO_2反opal球形光子晶体颗粒。首先用萃取辅助微乳液法合成PS opal球形光子晶体颗粒作为模板颗粒,然后利用液相沉积技术在模板颗粒空隙填充TiO_2,去除模板得其TiO_2反opal结构。样品的SEM图像和反射光谱结果显示,光子晶体颗粒球形度好,组装质量较高,微观结构排列有序;反射峰狭窄陡峭,反射强度较高。     

胶体模板法制备三维锗光子晶体

采用胶体模板法并通过简单可控的化学填充工艺制备了三维锗光子晶体;以单分散二氧化硅小球的蛋白石结构为模板,由氯化亚锗与丙烯酸化合制备得到3-三氯锗丙酸（Cl3GeCH2CH2COOH）白色粉末,以三氯锗丙酸的乙醇溶液作为锗源先驱体,低温水解得到β-羧乙基锗倍半氧化物,在600～660℃经H2还原后形成锗,由2％HF化学浸蚀消除模板．对终产物进行X射线衍射分析。结果表明：产物为多晶锗。通过扫描电子显微镜对终产物的形貌进行观察的结果表明：包裹有空气的锗壳球有序阵列已经形成。将先驱体浓度为0．6mol／L的溶液填入模板空隙后。壳层表面可以获得较为光滑致密的锗壳。     

单分散胶体颗粒的有序组装及其应用研究进展

本文综述了近1～2年来课题组在单分散胶体微球有序组装及其应用方面的研究进展.其中包括250～1300 nm宽尺寸范围单分散二氧化硅胶体微球的重力沉降自组织;旨在提高光子晶体折射率反差的TiO2/SiO2复合胶体微球的有序组装;硬模板与催化材料一步复合的二元胶体体系颗粒的有序自组装;一种高效的聚苯乙烯胶体颗粒的批量组装技术;低体积分数聚苯乙烯胶体晶体的制备;以及聚苯乙烯胶粒晶体作为可调谐三维非线性光子晶体在高开关对比的光子晶体光开关方面的应用,和作为制备有序大孔材料硬模板在大分子催化方面的应用等.     

聚苯乙烯胶晶模板法制备三维有序大孔SiO2材料

以聚苯乙烯微球(polystyrene microsphere)自然沉积形成的胶体晶体作模板,将以正硅酸甲酯制备的SiO2溶胶填充到模板间隙中,原位形成凝胶,最后通过焙烧除去模板,得到三维有序大孔SiO2.通过SEM检测,观察到六方和四方2种有序的大孔排列方式.大孔孔径及孔径收缩率分别为240nm和19%.2种排列中,大孔之间由小窗口连通,构成三维有序大孔结构.XRD显示,制备的3DOM材料由无定形SiO2组成.     

单分散SiO2/Ag/SiO2核壳结构微球制备及自组装光子晶体

应用湿化学方法,在SiO2微球表面先后包覆5 nm银层、20 nm SiO2介质膜,制备了直径约300 nm的单分散SiO2/Ag/SiO2核壳结构微球.用提拉技术实现微球的自组装,获得了长程有序的面心立方结构排列的光子晶体,并研究了其光学性能.结果表明:在可见至近红外波段存在非完全光子带隙;SiO2/Ag/SiO2球体自组装成的光子晶体并非完全密堆排列.     

胶晶模板法制备有序大孔炭材料研究进展

三维有序大孔炭材料（3DOCM）在光子晶体、催化剂载体、生物传感器和电极材料等方面具有潜在的应用前景，SiO2胶晶模板法是制备有序大孔炭材料的有效方法。制备步骤主要包括SiO2模板的组装、炭前驱填充及模板去除。本文综合所查文献，对有序大孔炭材料的制备及应用做了简要介绍。     

溶胶-凝胶模板法制备三维有序大孔TiO_2微球

采用无皂乳液聚合方法自制的单分散聚苯乙烯(PS)微球乳液为原料,并以PS微球自组装制备了有序胶体晶体模板("蛋白石"),采用溶胶-凝胶模板法制备了三维有序大孔TiO2微球("反蛋白石"),其孔呈六边形,孔径分布均一,约为200 nm,运用SEM,XRD对其形貌特征及晶型进行表征。结果表明,采用表面含有羧基的单分散聚苯乙烯微球及高的硅油粘度制得的模板有序度高;控制煅烧温度可以改变有序大孔TiO2微球的晶型,当煅烧温度为500℃时,其晶型为锐钛型,当煅烧温度为700℃时,其晶型则为金红石型。     

Fabrication of Patterned Inverse Opal Structure Through Physical Confinement Assembly and Selective Electrochemical Deposition

We develop a chemical modification-free process for fabrication of patterned photonic crystals (PhCs) of inverse opal structure. This process, involving photolithography, colloidal assembly, and electrochemical deposition, is potentially applicable for fabrication of practical optical devices. Polystyrene (PS) spheres were self-assembled onto pre-patterned substrates to serve as the sacrificial template. This template was then converted into a patterned inverse opal structure with selective electrochemical deposition. The thickness of the inverse opal structure can be easily controlled by adjusting the time of electrodeposition. We demonstrated the process with fabrication of a T-shape structure surrounded by an inverse opal structure of titania. Titania was chosen here as a representative demonstration material, and the process can be readily applied to other materials of desired characteristics.     

Filling behavior of ZnO nanoparticles into opal template via electrophoretic deposition and the fabrication of inverse opal

Combining colloidal crystal template (artificial opal) and electrophoretic deposition (EPD) process, well-ordered ZnO inverse opal can be formed by finding the optimum driving potential of EPD. Through providing the various driving potentials from −25 V, −10 V, −5 V to −2.5 V, the different mechanism of electrophoretically depositing ZnO nanoparticles into the colloidal crystal template was determined by the SEM observation of the filled templates. Because the nano-channels of colloidal crystal template are the network type, the results of surface jam, incomplete filling and perfect filling are found under specific applied voltages. The high-quality ZnO inverse opal can be only fabricated under the perfect nano-channel-filling condition. The filling behavior can be monitored dynamically by tracing the current transients, and the optimum conditions for filling the interstitial spaces of templates constructed from colloidal particles with 180 nm and 300 nm diameter can be obtained by applying a voltage of −5 V and −15 V, respectively. After the complete filling of ZnO nanoparticles into the colloidal crystal template consisting of 300 nm colloids, high-quality ZnO photonic crystal possessing an absorptive peak at the wavelength of 560 nm can be fabricated by removing the template. It is expected that the EPD can find extensive applications for preparing photonic crystals of various oxides only if their nanoparticles are available.     

One-step fabrication of N-doped TiO2 inverse opal films with visible light photocatalytic activity

N-doped TiO₂ inverse opal films were fabricated by a novel method through one-step coassembly of polymer colloidal spheres and titania precursor. This coassembly approach removed the need of preassembled colloidal crystal for precursor solution infiltration and respective chemicals for titania formation and nitrogen doping. Less crack films with well ordered inverse opal structure could be produced by adding appropriate amount of TiBALDH (titanium(IV)-bis-lactato-bis-ammonium dihydroxide) into the precursor solution. The films prepared at the optimized condition showed enhanced visible light photocatalytic activity, which could be attributed to both the N doping effect and their unique inverse opal structure.     

Preparation and characterization of electrodeposited Ag-doped ZnO inverse opals with a smooth surface

Ag-doped ZnO inverse opal structures were prepared by electrochemical deposition using polystyrene colloidal crystal templates. The Ag-doped ZnO structures had granular morphology, but this morphology became smooth using a three-dimensional (3D) porous template in the same electrolyte. The Ag-doped ZnO structures were characterized using energy-dispersive X-ray spectroscopy, and the lattice parameter was found to increase compared with undoped ZnO as verified by X-ray diffraction. Strong reflection photonic stop bands centered at 495 and 681 nm were detected from inverse opals templated from microspheres having diameters of 285 and 370 nm. The filling ratio of Ag-doped ZnO inverse opals using the template was lower than that of the uniform film growth of undoped ZnO. Moreover, photochemical cell analysis revealed that doped ZnO inverse opals with n- and p-type conductivities were successfully formed using electrolytes with different silver ion concentrations.     

大孔二氧化硅膜上纳米碳纤维层结构化催化剂载体的制备

1 INTRODUCTION Fast gas-liquid phase reactions over solid cata- lysts easily cause concentration gradient in reactors and catalysts because of relatively slow diffusion as well as the frequent occurrence of low concentration when gasses are dissolved. Such concentration gradi- ent caused by the limitation of mass transfer influ- ences the reaction rate as well as selectivity. Conven- tional strategies for gas-liquid-solid phase catalytic reactions comprise slurry reactors and trickle bed r…     

Template synthesis of structured titania using inverse opal gels

Inverse opal gels with varied content of acid groups were used as templates to synthesize structured crystalline titania materials. TiO₂ with opal, inverse opal, and gradient structure were obtained by altering composition of the gels and precursor concentration. The mechanism of the template synthesis by using opal gels was proposed.     

油性介质中组装二氧化硅胶体晶体薄膜

报道厂一种由粒径大于700nm的SiO2微球组装胶体晶体薄膜的方法。以一种密度较大的疏水性有机物替代水或醇类为分散剂,通过对SiO2微球表面进行疏水性处理改善其在油性介质中的分散性,采用改进的垂直沉积法在油性分散剂中制备SiO2胶体晶体。用扫描电子显微镜、红外光谱仪和紫外－可见光谱仪对SiO2胶体晶体薄膜的形貌、结构和光学性能进行了观察测试。结果表明;较大密度的分散剂能有效降低SiO2微球的沉降速度,组装成直径在700～2000nm范围的SiO2微球的胶体晶体。获得的SiO2光子晶体具有长程有序结构,并在近红外区具有显著的光子频率带隙。