Nanotube Arrays in Porous Anodic Alumina Membranes

This review summarizes the various techniques developed for fabricating nanotube arrays in porous anodic alumina membranes （AAMs）. After a brief introduction to the fabrication process of AAMs, taking carbons, metals, semiconductors, organics, biomoleculars, and heterojunctions as typical examples, attention will be focused on the recently established methods to fabricate nanotubes in AAM, including electrochemical deposition, surface sol-gel, modified chemical vapor deposition, atomic layer deposition, and layer-by-layer growth. Every method is demonstrated by one or two reported results. Finally, this review is concluded with some perspectives on the research directions and focuses on the AAM-based nanotubes fields.

Electrochemical modification process of anodic alumina membrane

The modification procedure of anodic alumina membrane(AAM) was studied. The AAM structure after modification was characterized by nickel nanowires prepared in AAM. Scanning electron microscopy was used to characterize the topography and structure properties of the AAM and nickel nanowires. The transformation of the current during the voltage reduction was studied. The mechanism of current and structure change during modification was discussed. The results show that a root structure produces after the AAM modification. The length of the root structure depends on the velocity of the voltage reduction. Slow voltage reduction leads to a large length of the root structure, otherwise, a short length of the root structure. At the end of the modification, the barrier layer is thin enough to be passed by electrons. Hence, the direct electrodeposition of one-dimensional nanowires can be carried out on the AAM with barrier layer and aluminum matrix successfully without any other treatments.

Structure and Magnetic Properties of Ni Nanowires Array Fabricated by Direct Current Electro-deposition in Anodic Alumina Membrane

Ordered nanostructure arrays of Ni-Al 2O 3 were synthesized by direct current electro-deposition in anodic alumina membranes (AAM). The investigation with a n electron microscope,an X-ray diffractmeter and a vibration sample magnetomete r indicates that the Ni nanowires, growing in the pores of AAM with about 45nm i n diameter, are monocrystalline and have a definite preferred crystallizing orie ntation. The magnetic behavior of the arrays and their mechanism were discussed.

EXPERIMENT AND RESEARCH ON DEVELOPMENT AND CHARACTERIZATIONS OF ANODIC ALUMINA MEMBR-ANE FOR USE IN HEMODIALYSIS

Objective The correlation between various formative conditions and the pore characterizationsof the anodic alumina membrane is investigated to seek the optimal conditions for the formation of anodic aluminamembrane. Methods High purity aluminum foils are used as the starting materials. The anodization is conduc-ted in three types of electrolytes, 3% sulfuric acid, 5% sulfuric acid and 2. 7% oxalic acid, respectively, with dif-ferent voltages at for 48h. The characterizations of the pore size, the effective porosity and the pore porosity areobserved and determined by scanning electron microscopy. The hydraulic conductances of the membranes are meas-ured to confirm that the pores are open and evaluate the permselectivity of the membranes. Results The experi-mental result shows that the ordered pore arrays are obtained for oxidation under our experimental conditions. Withthe increasing of the voltage, the pore size and pore porosity increased significantly (P <0.05) , while the effectiveporosity decreased significantly (P <0.05) with the same electrolyte. The pore size formed in 3% sulfuric acid or5% sulfuric acid is much smaller than in 2. 7% oxalic acid as an electrolyte. The hydraulic conductance of anodicalumina membrane that formed under our experimental condition is higher than those of the membranes are availablecurrently used in clinical. Conclusion The results suggest that the optimal conditions for the formation of anodicalumina membrane that used in hemodialysis are in 3% or 5% sulfuric acid with 12. 5V to 17. 5V at for 48h.

POROUS MEMBRANE TEMPLATED SYNTHESIS OF POLYMER PILLARED LAYER

The anodic porous alumina membranes with a definite pore diameter and aspect ratio were used as templates tosynthesize polymer pillared layer structures. The pillared polymer was produced in the template membrane pores, and thelayer on the template surfaces. Rigid cured epoxy resin, polystyrene and soft hydrogel were chosen to confirm themethodology. The pillars were in the form of either tubes or fibers, which were controlled by the alumina membrane pore surface wettability. The structural features were confirmed by scanning electron microscopy results.

纳米多孔铝阳极氧化膜的形成机理研究

为探讨多孔铝阳极氧化膜的形成机理,研究了不同气压条件下铝在磷酸溶液中的阳极氧化过程,发现在真空下进行阳极氧化,氧气析出非常明显。通过测定不同气压下的阳极氧化曲线,分析了致密膜向多孔氧化铝膜的转化和生长过程,结果显示氧气析出是导致氧化膜从致密膜向多孔膜转变的主要原因。提出了在氧化膜/电解液界面上氧气分子的聚集是造成表面条纹的新观点。通过氧化膜断面的SEM形貌表征,首次发现多孔膜的主孔道中存在分孔道。分孔道的产生说明析氧反应不但在致密膜/电解液界面发生,而且在多孔膜孔壁/电解液界面也同时发生。

多孔阳极氧化铝薄膜的制备

采用二次氧化的方法,在短时间内制备了多孔阳极氧化铝薄膜(AnodicAluminaMembrane,简称AAM),借助扫描电子显微镜(SEM),能谱分析(EDS)和X射线衍射(XRD)等测试手段分析了氧化铝膜的微观形貌和晶体结构,讨论了电解液温度波动和铝材表面缺陷对AAM表面形貌的影响。研究结果表明:制备的多孔氧化铝薄膜是非晶态氧化铝,在其表面孔径为50～70nm的六边形孔洞分布均匀,且垂直于薄膜表面平行生长。氧化过程中,电解液温度的稳定有利于形成规则的孔洞阵列;通过电化学抛光预处理,可有效去除机械划痕,避免薄膜表面沟壑状形貌的形成,提高了孔洞分布的均匀性。

氧化锌纳米线/管阵列的溶胶-凝胶模板法制备与表征

用溶胶-凝胶法在氧化铝模板中制备了直径约为15、30、50、60nm的有序氧化锌纳米线/管阵列.用扫描电镜(SEM)、透射电镜(TEM)和X射线衍射仪(XRD)对氧化锌纳米线/管的形貌、结构以及相组成进行了分析.结果发现,纳米线的形貌依赖于氧化铝模板中孔洞的形貌,纳米线的长度受控于氧化铝模板的厚度,外径与氧化铝模板的孔径相等.通过控制溶胶的浓度以及氧化铝模板在溶胶中的浸泡时间可以制备出纳米管.

Ni纳米线的制备及其微波吸收电磁性能

以氧化铝模板的孔洞为模型利用直流电沉积法制备了Ni纳米线.采用SEM,XRD,TEM对Ni纳米线的形貌和结构进行了表征.结果表明, Ni纳米线为单晶结构,沿[111]方向择优取向．把所制备的Ni纳米线和石蜡按质量比1:1:混合均匀后,利用同轴法测量其磁导率和介电常数,同时研究了该复合材料的吸波性能,计算得到了在不同厚度下的反射率曲线.研究发现,该纳米线／石蜡复合材料是一种介电损耗材料,在约9．5 GHz处介电损耗可达0．55,具有一定的吸波性能;当厚度为3 mm时,在6．5GHz处反射率可达-18 dB．

通孔氧化铝模板的强脉冲电化学剥离研究

利用0.3mol·L-1的草酸电解液,采用二步恒压阳极氧化法(30-50V)在高纯铝片上获得了高度有序的多孔氧化铝模板,利用HClO4-CH3OH混合溶液为电解液,利用还原反应产生的气体压力将多孔氧化铝膜从铝基底上剥离,获得了大面积(2cm×2cm)均匀无裂的多孔氧化铝的通孔模板,厚度为30-100μm;分析了影响孔径和阻挡层的因素和模板电化学剥离的机理;与其他剥离方法相比,该方法具有工艺简单、周期短、模板溶解少、无污染、模板韧性好, 可获得大面积均匀无裂膜,在纳米结构组装体系研究方面具有重要的实用价值.

阳极氧化氧化铝膜研究进展

全面归纳和分析了阳极氧化铝膜的结构,包括Keller模型、Murpy模型、Wood模型;综述了阳极氧化铝膜形成机理研究进展;总结了阳极氧化铝膜在磁学、光电、分离等方面的最新研究成果,并对阳极氧化铝膜的发展前景进行了展望。

基于氧化铝模板直接电沉积法镍纳米线的制备与表征

在未氧化铝和氧化铝之间经过降压剪薄阻挡层直接进行电沉积,采用不同电压进行电沉积制备了镍纳米线,并采用SEM,TEM和X射线衍射对所制备的镍纳米线进行了表征,研究了电沉积电压对纳米线结构的影响。结果表明:镍纳米线的外形决定于氧化铝模板的形貌,其直径和最大长度分别依赖于模板孔洞的直径和长度,当电沉积电压为1,1.5和2V时制备的镍纳米线为多晶结构,随着电沉积电压的升高,镍纳米线为沿[220]择优取向的单晶结构(电沉积电压分别为3V和4V),当电沉积电压进一步升高时,择优取向由[220]转为[111]方向(电沉积电压5V)。

二次阳极氧化方法制备有序多孔氧化铝膜

通过二次阳极氧化方法制备多孔氧化铝膜与一次阳极氧化方法制备多孔氧化铝膜孔排布规律性的对比 ,结果发现 ,二次阳极氧化方法制取的多孔氧化铝膜孔排布规律性明显好于一次阳极氧化法制取的多孔膜 .在几个微米范围内 ,孔呈理想的六角排布 .去除一次阳极氧化膜后 ,二次阳极氧化得以在更良好的表面进行 ,制取的氧化铝膜孔规律性和有序度更高 .

阳极氧化铝模板高有序孔的形成机理综述

阳极氧化铝模板法是合成纳米阵列材料的最常用的方法,然而有关氧化铝纳米孔的形成机理却没有达到统一的认识.利用26篇文献综述了氧化铝膜的理想结构和电场辅助的溶解模型、体积膨胀的应力模型、稳态孔的生长模型、临界电流的密度模型和梅花结构模型等5种不同的氧化铝纳米孔形成机理,最后对氧化铝模板的应用和发展前景提出了展望.

基于多孔阳极氧化铝的单层纳米柱阵列PMMA膜的制备

以阳极氧化法制作的多孔阳极氧化铝(PAA)膜为模板,采用旋涂法在PAA膜上浇注不同浓度的聚甲基丙烯酸甲酯(PMMA)/二甲基甲酰胺(DMF)溶液制作出了表面具有纳米柱结构的PMMA膜。实验结果显示采用磷酸溶液制备的PAA膜的孔径在300 nm左右且排列规整,采用质量分数为10%和20%的PMMA/DMF溶液制作的PMMA膜表面的纳米柱的粘连现象较严重,而采用质量分数为15%的PMMA/DMF溶液能够得到表面纳米柱间隔均匀的膜。具有表面纳米柱矩阵结构的高聚物的制作方法能够为仿壁虎脚材料和大比表面积材料的制作提供帮助。

H_2S燃料电池用质子传导膜及电池性能

研究了H2S燃料电池用的质子传导膜的制备及性能,考察了不同的Li2SO4与填充物Al2O3的匹配、微量元素B(H2BO3)的掺杂对膜及电池性能影响.研究了由H2S、(MoS2+NiS)/Li2SO4-Al2O3/pt、air构成的燃料电池在101.13kPa和600～700℃C时的电化学特性.在实验温度范围内,质子传导膜Li2SO4-Al2O3及整个电池系统在H2S气流下具有较好的化学稳定性.温度提高,质子传导膜的内阻减小,膜及电池性能变好.微量元素B的掺杂提高了膜的机械强度及膜的致密性,从而改善了电池的性能.在实验条件下,较适宜的B的掺杂量为2%～5%(质量百分数),较适宜的Li2SO4:Al2O3(质量比)为(3～5):1,电池最大输出电流密度和功率密度在700℃时分别达到200mA.cm-2和55mW.cm-2.

分子印迹纳米管膜的制备及对人体尿液中儿茶酚胺类药物的检测

以多巴胺(DA)为模板,多孔阳极氧化铝膜(AAO)为反应载体,合成了多巴胺分子印迹聚合物纳米管膜(AAO@MIP).利用扫描电子显微镜对分子印迹纳米管膜的形貌进行了表征,并用高效液相色谱(HPLC)研究了其对儿茶酚胺类(CLs)药物的吸附性能.实验结果表明,在最优萃取条件下,AAO@MIP纳米管膜对多巴胺、肾上腺素和去甲肾上腺素具有较高的选择性,3种儿茶酚胺类药物在0.50~300μmol/L浓度范围内呈良好的线性关系(r^2>0.9970);检出限(S/N=3)分别为15.5,12.6和22.5 ng/L.AAO@MIP纳米管膜对多巴胺的最大吸附容量可达82.1μmol/g;6次吸附-解吸附重复利用后,吸附容量仅降低3.3%.将AAO@MIP纳米管膜应用于萃取人体尿液中3种儿茶酚胺,样品加标回收率为74.0%~100.4%,相对标准偏差(RSD)为3.6%~6.8%.该方法简便、快速、选择性高,适用于检测人体尿液中的儿茶酚胺类药物的含量.

SnO_2纳米线阵列的制备及纳米器件的制作

采用简单的溶胶-凝胶方法在多孔阳极氧化铝模板(AAM)的微孔中制备了高度有序的SnO2纳米线阵列。XRD,SEM和TEM对样品进行了结构和形貌的表征,结果表明,高度有序的SnO2纳米线具有四方相的多晶结构,纳米线连续均匀;并对SnO2纳米线阵列的生长机理进行了探讨;最后用聚焦离子束沉积设备制作了单根SnO2纳米线器件。

草酸中纳米孔阵列阳极氧化铝膜的一步法制备及其形貌表征

报道了用一步阳极氧化法在经过预处理的高纯铝片上制备具有纳米孔阵列结构的阳极氧化铝膜(AAM)的技术,并用扫描电子显微镜(SEM)和原子力显微镜(AFM)对样品形貌进行了表征.结果表明,高纯铝片在0～20℃、0.1～0.5 mol/L的草酸溶液中用30～60V的直流电一步阳极氧化,再经过去铝和除阻挡层的过程,可制得纳米孔阵列阳极氧化铝膜.制得的阳极氧化铝膜中的孔,尺寸都在纳米级别,且大小均匀,相互平行排列成规整阵列,可用作制备纳米线阵列的模板.

电化学方法制备钛(Ⅳ)化合物纳米丝阵列

采用直流和脉冲电沉积法在阳极氧化多孔氧化铝薄膜的孔隙中制备了钛化合物纳米丝阵列。通过扫描电子显微镜、循环伏安曲线等手段研究了沉积条件如电子信号和电压等对所制备的纳米丝密度的影响。结果表明,应用脉冲电沉积法可制备致密的钛化合物阵列。