两步法制备多孔硅及其表征I:恒电流法(英文)

本工作通过采用电化学极 -化学氧化两步法在 1:1氢氟酸和乙醇溶液中制备出孔径约为 1～ 2 μm ,厚度大经为 6～ 10 μm的多孔硅样品 .首先将 0 .0 3A/cm2 的恒电流施加到p( 10 0 )硅片一段时间 ,然后将该硅片浸到 2 0 %的硝酸溶液中氧化一段时间 .通过此方法获得的多孔硅结构再进一步用扫描电子显微镜和拉曼光谱仪进行表面形貌和光学性质的考察 .所有制备出的多孔硅结构均有光致发光现象 .老化的多孔硅样品 (在干燥器放置一年 )的光致发光谱峰强度明显增强 ,但分别经过苯乙烯和十六碳烯 ( 1)两种有机溶剂处理 1h后的老化多孔硅样品的光致发光强度却没有显著改变 .     

优化金属辅助法腐蚀液组分制备多孔硅

金属辅助化学腐蚀法可以在无外加电路的条件下,在40%HF/30%H2O2/乙醇的混合溶液中完成多孔硅的制备,该方法简单快速。本文研究了金属辅助法腐蚀液体系各组分(HF、H2O2、乙醇)含量对多孔硅表面的SiHx成分和多孔层结构的影响,根据Si-H和Si-O的红外吸收峰强度的变化曲线优化了腐蚀液体系中各组分含量。在腐蚀液各组分体积比为V40%HF∶V30%H2O2∶V乙醇=2∶2∶1和腐蚀时间为4 min的条件下制备了形貌均匀、化学活性(SiHx成分)和多孔结构稳定性较好的多孔硅,并对金属辅助法与阳极蚀刻法制得的两种多孔硅进行比较,结果显示金属辅助法制备的多孔硅的化学活性和稳定性在后续的生物技术应用中具有明显的优越性。     

担载多孔Al2O3膜的制备和表征

研究了溶胶—凝胶法在多孔陶瓷载体上制备多孔Al_2O_3膜的工艺条件,发现在孔径为1.1～1.6μm的多孔陶瓷载体上必须经过多次重复浸渍—干燥—焙烧过程,才能制备出担载均匀的多孔A1_2O_3膜,不过对溶胶和多孔陶瓷载体进行适当的化学改性后,能够减少重复以上过程的次数。用BET法和透气实验对Al_O_3膜的孔径大小和透气性能进行了表征。     

多孔阳极氧化铝膜的制备研究

在直流恒压下,在不同的酸性溶液中对铝片实施两步阳极氧化制备多孔氧化铝膜,在磷酸溶液中制得的模板孔径大,并且电解时间缩短,加快了制备模板的过程。同时利用阳极氧化初期电流密度的变化,分析了多孔氧化铝膜的形成机理。     

溶胶凝胶法制备取向性氧化铝超滤陶瓷膜

用金属醇盐的溶胶-凝胶法在多孔α-Al_2O_3衬底上制备了孔径均一的γ-Al_2O_3超滤膜.经X射线衍射仪、扫描与透射电子显微镜以及静态氮吸附等手段对膜的结构、形貌与孔径大小分布等进行了表征.实验发现顶层膜取向生长,膜厚受浸取时间、溶胶浓度、粘度和实验温度等因素影响.典型条件下可在20mm×20mm衬底上制备孔径均一、大小为3.8～4.8nm和厚度2μm左右的无裂纹、无孔洞等表面缺陷的多孔γ-Al_2O_3陶瓷膜.     

多孔硅/硝酸钆复合材料制备与表征

多孔硅/硝酸钆复合材料因具有爆炸能量高和环境危害小等特点而受到世界各国广泛关注.采用电化学阳极氧化法制备新鲜多孔硅并滴加硝酸钆形成复合材料,表征其化学组成与结构.结果表明,当电解液HF与EtOH体积比为1∶1、电流密度为50mA·cm-2、阳极氧化时间为30min时,形成的多孔硅孔隙率较大,适宜与硝酸钆形成复合材料;与新鲜多孔硅相比,滴加硝酸钆乙醇溶液的多孔硅在1675、1534、1382和1217cm-1出现了4个新的吸收峰,结合N1s和Si2p结合能有明显化学位移的现象,表明硝酸钆乙醇溶液与多孔硅之间存在相互作用,结构中有-NH2形成,表面Si-Hx键被氧化为si-O键;当电火花触发时,观察到多孔硅/硝酸钆复合材料爆炸现象.     

光化学氧化对多孔硅稳定性及SO2传感性能影响

采用光化学氧化方法对多孔硅进行后处理,获得具有良好稳定性的氧化多孔硅;采用SEM、AFM、FT-IR进行表征;通过SO2传感实验,评价其光致发光谱的变化。结果表明,采用电化学阳极氧化制备的新鲜多孔硅在空气中稳定性较差,SEM图表明其膜层分布有120×40μm的长方形小块,光化学氧化后使该长方形小块进一步分裂变细;AFM图表明,新鲜制备的多孔硅经稳定化处理后,表面硅柱宽度由700～750 nm变为300～350 nm,高度由50～58 nm变为40 nm;出现Si—O键(1 114 cm-1)和OSi—H键(2 249 cm-1)的振动峰;该氧化多孔硅在SO2介质中呈可逆的荧光猝灭特征,荧光峰的位置不随SO2浓度变化而发生移动,稳定性较好。     

湿化学法制备硅纳米线阵列及其光电化学产氢性能分析

为了探究不同方法条件下制备的硅纳米线阵列电极产氢性能异同,文中分别采用了两步金属辅助催化无电刻蚀法、一步金属辅助催化无电刻蚀法以及阳极氧化法来制备硅纳米线阵列用作为光电分解水电池光阴极材料.通过FESEM、XRD和UV-Vis-IRDRS等手段对实验样品的形貌、晶型、减反性表征,发现相比于其他2种方法所得硅纳米线样品,两步金属辅助催化无电刻蚀法制备的硅纳米线结构晶型保持更好,表面缺陷更少.光电化学测试表明两步金属辅助催化无电刻蚀法制备的硅纳米线光电化学性能表现最优,其光电流密度值是一步法的4倍,阳极氧化法的40倍;转移电荷电阻仅是一步法制备的硅纳米线阵列阻值的1/3,阳极氧化法制备的1/1000.     

担载多孔Al2O3

研究了溶胶－凝胶法在多孔陶瓷载体上制备多孔Ａｌ２Ｏ３膜的工艺条件，发现在孔直径为１．１和１．６μｍ的多孔陶瓷载体上必须经过多次重复浸渍－干燥－焙烧过程，才能制备出担载均匀的多孔Ａｌ２Ｏ３膜，对溶胶和多孔陶瓷载体进行适当的化学改性后，能够减少浸渍－干燥－焙烧过程重复的次数，对Ａｌ２Ｏ３膜的孔径大小和透气性能进行了表征。     

用于气体传感器的多孔硅的制备方法研究

分别采用化学刻蚀法、电化学腐蚀法和铂助腐蚀法在室温下制备了应用于气体传感器的纳米级多孔硅,并且对其表面形貌及厚度进行了表征。结果表明,3种方法制备的多孔硅孔径从5～100nm不等,并且3种制备方法各具优缺点,可根据实际需要来选择合适的制备方法。     

Effects of Ultraviolet Illumination and Pre-treatments on Porous Silicon Formation

Although porous silicon is readily formed by anodizing silicon wafers in HF-based solutions, its application in silicon-based optoelectronic devices is greatly limited due to its poor stability and low luminescence yield. It is well recognized that the nature of silicon wafers and the fabrication condition parameters significantly influence uniformity, stability and optical properties of porous silicon. In this work, the ultraviolet illumination and pre-treatments were investigated for porous silicon formation. The surface morphologies and optical properties of the samples were also studied.     

Surface morphology dependent photoluminescence from colloidal silicon nanocrystals

Monodisperse 1-2 nm silicon nanocrystals are synthesized in reverse micelles and have their surfaces capped with either allylamine or 1-heptene to produce either hydrophilic or hydrophobic silicon nanocrystals. Optical characterization (absorption, PL, and time-resolved PL) is performed on colloidal solutions with the two types of surface-capped silicon nanocrystals with identical size distributions. Direct evidence is obtained for the modification of the optical properties of silicon nanocrystals by the surface-capping molecule. The two different surface-capped silicon nanocrystals show remarkably different optical properties.     

Synthesis of anodic silicon oxide films in water-organic solutions containing orthophosphoric acid

Variations in electrophysical properties of anodic silicon oxide at the surface of semiconductor silicon are studied as a function of the composition of electrolytic solutions containing orthophosphoric acid and the conditions of reaching the final formation potential. The optimum conditions for the formation of anodic SiO₂ coatings that include phosphorus-containing admixtures are determined, the coatings being intended for application as diffusates in nanoelectronics.     

Laser Flash Photolysis of Phthalocyanines in Solution and Microemulsion

Triplet state formation (Φ_isc) and properties (ε_T-T, τ_T) of phthalocyanine (HPC) and zinc phthalocyanine (ZnPC) have been characterized in homogeneous solutions (1-chloronaphthalene, 1-propanol) and in microemulsion by investigating the variation of the transient optical density as a function of the intensity of the exciting laser. Experimental results follow the theoretically predicted dependence only for very low intensities of the exciting pulse. At higher intensities, a more complicated scheme of primary reactions has to be taken into account, implicating qualitative restrictions in the application of saturation experiments. The observed transients at high-intensity excitation are interpreted as being perturbed by aggregational phenomena.     

Electrodeposition of nanocrystalline zinc from acidic sulfate solutions containing thiourea and benzalacetone as additives

Nanocrystalline zinc coatings were produced by pulse electrodeposition in acid sulfate bath containing thiourea and benzalacetone additives and characterized by X-ray diffraction and scanning electron microscopy techniques. The influence of benzalacetone concentration and pulse peak current density on the grain size and crystallographic orientation of zinc deposits was investigated. Zinc electrodeposited from additive-free solutions or with one of the two additives is not composed of nanosized crystals. The mixture additives of thiourea and benzalacetone give rise to the formation of particle-like nanocrystalline zinc with a (10ī1) random orientation. A change in peak current density from 2 to 1 A/cm² only increases the grain size from 60 to 62 nm.     

Picosecond pulse radiolysis study of highly concentrated nitric acid solutions: formation mechanism of NO3• radical

The formation of nitrate radical, NO(3)(?), is observed for the first time directly by picosecond pulse radiolysis of highly concentrated nitric acid solutions. The experimental yield of NO(3)(-) ionization is deduced from the pulse-probe transient absorption measurements in the visible region where this radical absorbs. On the basis of the value of the extinction coefficient of nitrate radical at 640 nm equal to 1300 M cm(-1), the experimental yield of NO(3)(?) at 20 ps is found to be around 0.36 × 10(-7), 1.33 × 10(-7), and 2.85 × 10(-7) mol J(-1) for 1, 3.5, and 7 M nitric acid solutions, respectively. Relative to the dose absorbed by nitric acid by the direct effect, we find an unexpected high formation yield of the nitrate radical within the electron pulse. Therefore, we suggest that the trapping of the positive hole, H(2)O(?+), by NO(3)(-) also contributes to the formation of NO(3)(?) within the electron pulse. Moreover, after the pulse and within 4 ns, the beginning of the reaction of OH(?) radical with undissociated nitric acid is observed for the most concentrated nitric acid solution.     

Differential pulse voltammetric determination of trace silicon at a glassy carbon electrode

The heteropoly molybdosilicic acid complex produces five well-developed differential pulse voltammetric peaks at a glassy carbon electrode in citrate buffer solutions containing 20% 2-butanone with peak potentials in the neighborhood of +0.05 V, -0.10 V, -0.25 V, -0.50 V and -0.65 V (vs. Ag/AgCl, 0.1 M KCl). The peak current at each peak potential is clearly developed and is proportional to the silicon concentration; the linear range for the most useful peak at +0.05 V is 10^-5–10^-7 M silicon, the lower limit being fixed by the blank conditions. Nickel-base alloy samples and water samples were analyzed with satisfactory results.     

预处理对多孔硅形成过程的影响(英文)

本工作初步探讨了开路电位下对硅片进行预处理时多孔硅的形成过程 .电化学极化实验、扫描电镜和拉曼谱学的研究表明 ,预处理可以加速硅 /溶液界面上的化学或电化学反应 ,从而加快多孔硅的生长过程 ,最终导致光致发光的光谱红移 .多孔硅的厚度随预处理时间的增长而减小     

Interactions of amines with silicon species in undersaturated solutions leads to dissolution and/or precipitation of silica

The biogeochemical silicon cycle is the focus for many researchers studying the dissolution of silicon species from quartz, amorphous, and biogenic silica. Furthermore, the precipitation of biogenic silica by diatoms, radiolarian, sponges, and plants is also a popular focus for research. The ornate silica structures created by these species has attracted interest from biomaterial scientists and biochemists who have studied mineral formation in an attempt to understand how biogenic silica is formed, often in the presence of proteins and long chain polyamines. This article is at the interface of these seemingly distinct research areas. Here we investigate the effect of a range of amines in globally undersaturated silicon environments. Results are presented on the effect of amine-containing molecules on the formation of silica from undersaturated solutions of orthosilicic acid and globally undersaturated silicon environments. We sought to address two questions: can silica be precipitated/harvested from undersaturated solutions, and can we identify the silicon species that are most active in silica formation? We demonstrate that none of the bioinspired additives investigated here (e.g., poly(allylamine hydrochloride), pentaethylenehexamine, and propylamines) have any influence on orthosilicic acid at undersaturated concentrations. However, under globally undersaturated silicon concentrations, small molecules and polymers containing amine groups were able to interact with oligomers of silicic acid to either generate aggregated materials that can be isolated from solution or increase rates of oligomer dissolution back to orthosilicic acid. Additional outcomes of this study include an extended understanding of how polyelectrolytes and small molecules can promote and/or inhibit silica dissolution and a new method to explore how (bio)organic molecules interact with a forming mineral phase.