介孔C/SiO2粉体的制备及对阳离子型染料的吸附

采用吸附法处理染料废水需要合适的吸附剂。利用溶剂蒸发自组装法,以甲阶酚醛树脂为碳源、介孔SiO2粉体为载体制备介孔C/SiO2粉体,表征所制C/SiO2粉体的结构,研究C/SiO2粉体对阳离子型染料亚甲基蓝和阳离子红X-GRL的吸附性能,并与相同条件下制备的非负载的多孔C粉体以及介孔SiO2载体进行比较。结果表明,介孔C/SiO2粉体的孔窗口为11~18 nm,比表面积为303 m2.g-1,比孔容为1.11 cm3.g-1;C/SiO2粉体对这两种染料吸附量均高于C粉体和SiO2载体;在pH≤10的范围内,吸附量随pH值增大而显著提高。     

多孔炭物理化学结构及其表征

以碳为基本骨架的多孔炭因具有丰富的孔隙结构和表面化学宫能团,在吸附分离、催化、电子等领域应用广泛.在阐述多孔炭孔结构（物理结构）和表面化学宫能团（化学结构）基础上,重点介绍了透射电镜等可直接观察多孔炭孔结构的表征方法及Dubinin微孔充填理论、平均场密度泛函理论、吸附法、压汞法等表征多孔炭孔结构的主要理论及方法,以及...     

负载激光染料香豆素151的MCM-41粉体及其纤维的光学性质研究

通过结晶包覆的方法将激光染料香豆素151成功地负载到具有介孔结构的MCM-41粉体和纤维中,制备了具有光致发光特性的MCM-41粉体和纤维材料,并通过SEM,SAXRD,UV-Vis和PL进行了表征.     

稀土离子在多孔阳离子交换剂内的扩散动力学

研究了稀土离子在Amberlyst15、D001、XN1010多孔树脂内的自扩散。结果表明,扩散过程遵循二级分散扩散机制。用粒内扩散方程求算了有效粒内扩散系数e,将e分解为树脂孔道扩散系数p及树脂固相扩散系数s,p与该离子在外部溶液中的自扩散系数相近,而s接近于与实验用的多孔树脂交联度相同的凝胶树脂内的自扩散系数值。     

甲苯二异氰酸酯与乙二胺沉淀聚合一步法制备聚脲多孔材料及其表征

以甲苯二异氰酸酯和乙二胺为单体,通过沉淀聚合一步到位制备了富含胺基的聚脲多孔材料.探讨了反应时间、溶剂种类及混合溶剂配比对聚脲多孔材料性能的影响.通过BET和压汞法对聚脲多孔材料的孔结构进行了表征,用扫描电子显微镜表征了材料的形貌,用X-射线衍射仪测试了材料的结晶性能.结果表明,聚合反应进行48 h后多孔材料的胺基含量不再变化,所得聚脲为典型多孔材料且部分结晶.与丙酮相比,以乙腈作反应介质制备的聚脲的比表面积和孔体积较大,孔径分布较宽.以乙腈和丙酮混合溶剂作反应介质,通过改变混合溶剂的配比可以改变材料的孔结构.     

超细多孔TiO2的制备及机理研究

以硫酸和氨水为原料,以乙醇为分散剂,采用化学沉淀法合成了超细多孔TiO₂,并详细考察了pH值和反应温度对TiO₂前驱体结构的影响.多孔TiO₂随着焙烧温度的提高,比表面有所降低,导致这一现象的原因是晶粒生长及相转变.从孔分布曲线分析可知,200℃得到样品的一部分微孔,在较高温度的焙烧过程中被烧结,得到了孔分布更为均匀的多孔粉体,由TEM照片可清晰看到多孔TiO₂的空间网络结构.     

CO_2吸附法表征材料孔结构的研究进展

对于多孔材料孔结构的表征,N_2吸附(77K)是最常用的方法。但随着多孔材料种类的日益丰富,CO_2吸附表征引起人们越来越广泛地关注。CO_2作为N_2吸附的有效补充,被用于各种传统和新型多孔材料的表征,特别是极微孔结构的探测。概述了CO_2吸附法表征多孔材料孔结构的现状,总结了CO_2吸附等温线的类型及测试条件,阐述了用CO_2吸附数据分析材料的比表面积、孔容和孔径分布时常见的各种问题。     

多孔氧化铜空心微球的一步法制备及其光催化性能

采用一步法成功制备出多孔氧化铜空心微球,用SEM、XRD和FTIR对制得的样品进行了表征。研究发现,碳源、反应温度、反应时间、CuSO4浓度等实验条件在多孔微球的制备过程中起着重要作用。在实验结果的基础上,提出了多孔氧化铜空心微球的形成机理。制备的多孔氧化铜空心微球的比表面积为409 m2.g-1,平均孔径为3.15 nm,总孔体积为0.256 cm3.g-1,这种空心微球具有量子尺寸效应并对罗丹明B有较高的光催化性能。     

介孔硅与大孔硅的结构、电学和气敏特性

采用双槽电化学腐蚀法在P型单晶硅表面制备两种多孔硅.根据它们的孔径将它们分为介孔硅和大孔硅.使用扫描电子显微镜(SEM)观察两种多孔硅表面和断面形貌,介孔硅和大孔硅的表面化学键用傅里叶变换红外(FTIR)光谱仪来研究,通过I-V特性测试表征两种多孔硅电学特性,随后在室温下测试其气敏特性.结果表明:介孔硅具有较高的气体灵敏度,大孔硅具有较好的气体响应恢复特性.介孔硅对NO2气体具有较好的选择性,大孔硅对NH3气体具有较好的选择性.     

轻质热塑性复合片材吸声性能

以聚丙烯树脂和玻璃纤维为原料,依托预混粉体浸渍专利技术,无需发泡剂,制备出轻质多孔、吸声降噪的轻质热塑性复合材料.利用SEM、偏光显微镜和毛细渗透实验研究了材料的微结构与吸声特性的关系.通过使用驻波管测量材料的吸声系数,分析了材料的厚度和面密度对材料吸声性能的影响.结果表明:材料的多孔微结构有利于声能的吸收;4 mm厚的片材,峰值吸声系数达0.65;材料厚度和面密度的增大,能显著提高其吸声性能,特别是低中频吸声性能.     

Frequency Response Method for Measuring Mass Transfer Rates in Adsorbents via Pressure Perturbation

A new apparatus for the measurement of equilibria and dynamics for gas-phase adsorption systems is utilized to examine the adsorption of carbon dioxide on BPL activated carbon. The apparatus has a flow-through configuration. For dynamics, with constant inlet flow, pressure within the adsorbent-containing section is varied sinusoidally, and the time-dependent outlet flow rate is measured to determine an amplitude ratio and phase lag. Studies are made of temperature effects and particle size effects. Results are compared with several mathematical models. Frequency response data show that the BPL system follows surface (or micropore) diffusion kinetics. The rate of adsorption for the activated carbon is found to be only weakly dependent on the bulk particle size.     

Low-temperature adsorption of hydrogen on nanoporous aluminophosphates: effect of pore size

Several nanoporous aluminophosphates (AlPOs) have been used to analyze the effect of pore diameter on the hydrogen adsorption characteristics. The heat of adsorption and adsorption capacity per unit micropore volume increase with decreasing pore size. AlPOs with smaller micropores favorably adsorb hydrogen at relatively low pressures. This work demonstrates that small pore size and large micropore volume are beneficial for high hydrogen uptake.     

New apparatus for measuring surface areas as low as 0.1 cm2

An apparatus is described which permits accurate determination of gas adsorption of solids having lower adsorptive capacity. Conventional measurement of gas uptake by solids having surface areas less than 1 m² is not generally feasible at subatmospheric pressure. The small pressure drop due to adsorption is easily lost in the noise created by ambient temperature fluctuations. Possible experimental errors in the volumetric measurement of gas uptake due to temperature fluctuations were greatly reduced by using an apparatus whose reference and sample adsorption cells are disposed in a lateral symmetry. The apparatus consists of a differential micromanometer whose two arms are connected in a lateral symmetry to a pair of sample and reference burets of nearly equal volume for dosing gas into sample and reference cells also of nearly equal volume. When the two cells are immersed in the same temperature bath this design greatly reduces measurement uncertainties due to fluctuations in the temperature. Surface areas as small as 300, 1 and 0.1 cm² were measured through volumetric gas uptakes of nitrogen at 78 K, krypton at 78 K and xenon at 90 K, respectively.     

Adsorption of organics on MSC5A in supercritical CO2, chromatographic measurements & stop & go simulation

Chromatographic measurements were made for the adsorption of benzene, toluene and m-xylene on molecular sieving carbon (MSC) in supercritical fluid CO₂ mixed with organics. Supercritical chromatograph packed with MSC was used to detect pulse responses of organics. Adsorption equilibria and adsorption dynamics parameters for organics were obtained by moment analysis of the response peaks. Dependences of adsorption equilibrium constants, K ^?, and micropore diffusivity,?D, on the amount adsorbed were examined. The dependencies of adsorption equilibrium constants, K ^?, and micropore diffusivity, D, of benzene, toluene and m-xylene, on molarity of benzene with each parameters of temperature or pressure were obtained. It was found that the values of K ^? and D for an organic substance depended on the amount adsorbed of other organics strongly. And stop & go method was used as simulation method of perturbation chromatography for investigating adsorption equilibrium and rate. Numerical solution for multicomponent chromatogram in time domain could be obtained by appropriate model equations with experimental conditions. This simulated chromatogram can be compared with experimental chromatogram to determine the adsorption equilibrium and rate parameters. In addition, molecular simulation of multicomponent adsorption equilibria was performed, and potential parameters were determined by comparing the simulation with experimental results. Simulation soft ware is Cerius2 (Version?4.2) made by MSI. The purpose of performing simulation is to elucidate an adsorption mechanism on the molecule level.     

Modeling gas adsorption and transport in small-pore titanium silicates

Engelhard titanium silicate, ETS-4, is a promising new adsorbent for size-selective separation of mixtures of small gases, a leading industrially important example of which is methane-nitrogen separation. Single component equilibrium and kinetics of oxygen, nitrogen, and methane adsorption in Na-ETS-4 and cation-exchanged Sr-ETS-4, measured in an earlier study over a wide range of temperatures and pressures, are analyzed in this study. The adsorbent crystals were synthesized and pelletized under pressure (without any binder), thus giving rise to a bidispersed pore structure with controlling resistance in the micropores. Change in equilibrium and kinetics of adsorption of the aforementioned gases in Sr-ETS-4 due to pore shrinkage with progressively increasing dehydration temperature has also been investigated. Differential uptakes have been measured at various levels of adsorbate loading, which has allowed the elucidation of the nature of concentration dependence of micropore diffusivity. Both homogeneous and heterogeneous models are examined on the equilibrium data, while a bidispersed pore diffusion model is able to capture the differential uptakes very well. On the basis of chemical potential gradient as the driving force for diffusion, the impact of isotherm models on the concentration dependence of micropore diffusivity is also analyzed. It is shown that pore tailoring at the molecular scale by dehydration can improve the kinetic selectivity of nitrogen over methane in Sr-ETS-4 to a promising level. The models investigated are evaluated to identify essential details necessary to reliably simulate a methane-nitrogen separation process using the promising new Sr-ETS-4 adsorbent.     

Thermal diffusivity measurement of ceramic materials used in spraying of TBC systems

The basic goal of this article was thermal diffusivity characterization of ceramic materials used in thermal barrier coating (TBC) systems for depositions of the insulation layer and characterization of the materials’ morphology and remanufacturing process. The base material was oxide 8YSZ (ZrO_2? ×?8Y₂O₃), which is usually dedicated to deposition of an insulating top layer in TBC systems. The data related to thermal properties such as thermal diffusivity and thermal conductivity are widely presented in the literature, but there is lack of information about the morphological form of investigated materials, and the presented results vary widely. Data on thermal properties based on the literature sources are inadequate for the real morphological form of materials used in the experiment (e.g., massive or single crystalline material vs. plasma-sprayed coatings), which consequently gives an unsatisfactory accuracy of the obtained numerical simulations by MES methods. This article presents the characterization of thermal diffusivity of the commercial 8YSZ ceramic material synthesized or remanufactured by different routes, which is investigated in the forms of pressed powder pellet (two commercial nano-sized powders with different morphologies), sintered pellets (one commercial powder, solid-state co-precipitated reacted powder of 8YSZ type), and a two-layered coating system of In625?+?NiCrAlY/8YSZ type. The range of analysis included morphological investigations of different types of powders in initial conditions and after remanufacturing (sintering, thermal spraying) as well as the thermal diffusivity analysis by the laser flash method. The obtained data were corrected by porosity factor and compared to each other. The best similarity for obtained thermal diffusivity data was found for commercial powers of HOSP^TM type after pressing and sintering processes and calculated (2-layered model) value of thermal diffusivity for two-layered system of In625/8YSZ TBS system. The results showed that there are significant differences in thermal diffusivity values for materials with different morphological forms.

     

Adsorption separation performance of H2/CH4 on ETS-4 by concentration pulse chromatography

To exploit an effective adsorbent to separate hydrogen and methane, microporous titanium silicate molecular sieve NaETS-4 was synthesized and modified by strontium. The adsorption characteristics and diffusion behaviors of the prepared titanosilicate molecular sieve were studied by concentration pulse chromatography. And the effects of ion-exchange and dehydration temperature on adsorbent structure and gas diffusion were also discussed. The results showed that the thermal stability and Henry＇s Law constants were enhanced and micropore diffusivity decreased after exchanging Na＋ with Sr2＋. With the increase of dehydration temperature, Henry＇s Law constant and micropore diffusivity of CI-I4 decreased in both NaETS-4 and SrETS-4. While for 1-12 in SrETS-4, the increase of Henry＇s Law constant and the decrease of diffusion rate can be attributed to the shrinks of pore diameter resulting from the relocation of Sr2＋. Correspondingly, the kinetic selectivity of H2/CH4 reached 8.91 indicating its potentiality in separating H2 and CH4.     

Low-temperature adsorption/storage of hydrogen on FAU, MFI, and MOR zeolites with various Si/Al ratios: effect of electrostatic fields and pore structures

Several zeolites, such as faujasite, mordenite, and ZSM-5, with various aluminum contents have been used to analyze the effect of aluminum or cation concentration (strength of electrostatic field) on hydrogen adsorption at low temperature. Irrespective of the zeolite structure, the adsorption capacity, isosteric heat of adsorption (-DeltaHads), surface coverage, and micropore occupancy increase with increasing aluminum content of a zeolite. Zeolites with a higher amount of aluminum favorably adsorb hydrogen at relatively low pressures. For zeolites with similar aluminum contents, the adsorption capacity, isosteric heat of adsorption, surface coverage, and micropore occupancy are in the order of mordenite>ZSM-5>faujasite, probably due to differing pore sizes and the presence or absence of pore intersections. This work demonstrates that zeolites with strong electrostatic fields and narrow pores without intersections are beneficial for high hydrogen uptake.