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...     

活性炭吸附脱除水中抗生素污染物研究进展

活性炭对抗生素污染物吸附性能的主要影响因素是其孔结构和化学结构性质。活性炭孔结构的构建方法可分为活化法、模板法和原位法,化学结构性质的调控方法可分为后处理法和原位法,掺杂的元素有氧、氮、硫、磷、硼等。围绕抗生素污染物的吸附,综述了活性炭的性质调控方法,并展望了活性炭性质调控的发展方向,为新型高效活性炭吸附剂的构建及吸附机理的研究提供了指导与借鉴。     

吸附剂的物理结构和表面性质的研究——酸处理对硅胶孔结构和吸附性能的影响

测定了样品的孔结构参数和水蒸气吸附性能。试验表明:用pH3.00酸化的自来水洗涤酸性水凝胶可制得典型的细孔硅胶;用3mol/L以上的硫酸溶液浸泡酸性水凝胶可制得平均孔半径约为300的特粗孔硅胶。     

膨胀石墨微观孔结构的特点及其表征

膨胀石墨是一种疏松多孔的颗粒状新型碳材料［1，2］．由于在膨化过程中产生了丰富的孔结构，新鲜表面大为增加[3，4]，因此具有很好的吸附性能．探讨这种新材料孔结构的特征对于深入研究其吸附行为有重要意义．但目前尚没有对膨胀石墨孔结构进行系统研究的报导，本文采用低温N     

活性碳纤维的结构修饰及其吸附氙性能的研究

活性炭纤维对氙的吸附容量与其孔结构密切相关，为了提高活性炭纤维对氙气的吸附容量，本文分别用亚甲基蓝、对硝基苯酚等有机物，或氯化钠、碘等无机化合物填充的方法修饰活性炭纤维的孔结构；以及利用高锰酸钾或硝酸等氧化处理修饰活性炭纤维的表面化学性质，同时，利用低温氮等温吸附表征了这些改性活性炭纤维的孔结构，以及通过光电子能谱表征了改性活性炭纤维的表面化学结构，上述化合物充填或氧化改性活性炭纤维对氙的吸附性能的研究结果表明，适量化合物填充，或合适浓度硝酸对活性炭纤维的表面处理，可以有效地修饰活性炭纤维的孔结构或改变活性炭纤维表面对氙的亲和力。因而可有效地提高改性活性炭纤维对氙的吸附容量。     

几种植物基活性炭材料的表面结构与吸附性能比较——(II)表面化学结构与吸附性能研究

用X-射线光电子能谱对3种植物基活性炭材料:椰壳活性炭 (CAC4)、剑麻茎基活性炭(SSAC)和剑麻基活性碳纤维 (SACF) 的表面化学结构进行了表征,并研究和对比了它们的吸附性能,包括对碘、苯酚和亚甲基蓝的液相吸附性能,对有机蒸汽的吸附性能以及对Au3+的还原吸附性能等。结果表明,3个样品表面均含有多种含氧官能团,吸附能力SACF>SSAC> CAC4。样品的吸附性能主要取决于自身孔结构,与其表面化学结构也有密切的关系。     

几种植物基活性炭材料的表面结构与吸附性能比较-(Ⅱ)表面化学结构与吸附性能研究

用X-射线光电子能谱对3种植物基活性炭材料椰壳活性炭(CAC4)、剑麻茎基活性炭(SSAC)和剑麻基活性碳纤维(SACF)的表面化学结构进行了表征,并研究和对比了它们的吸附性能,包括对碘、苯酚和亚甲基蓝的液相吸附性能,对有机蒸汽的吸附性能以及对Au3+的还原吸附性能等.结果表明,3个样品表面均含有多种含氧官能团,吸附能力SACF＞SSAC＞CAC4.样品的吸附性能主要取决于自身孔结构,与其表面化学结构也有密切的关系.     

国产硅胶热稳定性的研究

本文研究直至940°,青岛细孔硅胶、粗孔硅胶、泰仁硅胶及英国细孔硅胶的热稳定性。并测定水、苯、环己烷蒸气在上述硅胶上的吸附等温线。所得结果如次: 1.经硝酸处理的纯硅胶的热稳定性较未经处理者大。后者于940°灼烧几失去所有的多孔性和活性。但相同条件下,粗孔硅胶之热稳定性较细孔硅胶大。 2.硅胶经600°以上的热处理,其吸水等温线和憎水性硅胶相同,低压下呈凹形。 3.无论细孔或粗孔硅胶,灼烧温度增高,比表面和微孔总体积减少,但硅胶之平均孔半径几不变。 4.较低温下,加热时间(直至四十四小时)不影响硅胶的吸附性能;但高温下(细孔硅胶在600°以上,粗孔硅胶在800°以上)吸附量随灼烧时间延长而减少。 5.硅胶表面经基脱水后再浸水可部分水合,但灼烧温度超过980°,则不能再水合。 6.苯蒸气在粗孔硅胶上的吸附-解吸等温线呈显著的滞后圈,而在细孔硅胶上则无。 7.据水蒸气吸附的结果,说明青岛细孔硅胶的孔性结构与英国B.D.H.细孔硅胶相似。     

聚丙烯腈活性炭纤维对硫化氢的常温吸附

聚丙烯腈活性炭纤维（PAN-ACF）对硫化氢（H2S）有比其他活性炭材料更强的吸附能力。H2S在PAN-ACF上的吸附是一个兼具物理吸附特征的化学吸附、催化转化过程。其化学吸附位主要位于微孔表面。吸附过程为：H2S分子首先被物理吸附进入微孔空间,而后在微孔表面的化学吸附位上进行包含电子转移的化学吸附、催化氧化,在炭表面产生相对稳定的化学结构。     

孔结构对活性炭吸附水溶液中铅离子的影响

选取三种表面化学性质相近的活性炭(AC),通过等温吸附实验考察活性炭对水溶液中铅离子的吸附性能,利用扫描电子显微镜(SEM)观察活性炭的表面微观形貌,通过低温(77 K)液氮吸附测定活性炭的比表面积和孔容,并分别以密度泛函理论(DFT)和Barrett-Joyner-Halenda (BJH)法计算微孔和中孔的孔径分布.结果表明:选用的三种活性炭AC1、AC2、AC3在比表面积和总孔容上呈依次下降的趋势,但表面开放孔均匀分布的AC2,具有最高的饱和吸附量,孔结构类似颗粒堆积孔的AC3,具有与表面开放孔分布集中的AC1相近的饱和吸附量;通过对孔结构与吸附量的关联分析可知,在活性炭吸附铅离子的过程中, 0.4-0.6 nm的孔是有效吸附孔, 10.5-20.6 nm、20.6-55.6 nm、5.2-10.5 nm三个区间的孔则会对吸附产生阻碍作用.     

Adsorption of Acid Orange II from Aqueous Solution by Plasma Modified Activated Carbon Fibers

As a main composition of dye wastewater, organic pollutant which has a negative effect on the environment can be effectively removed by active carbon adsorption. In the present work, activated carbon fiber (ACF) was modified by a novel modification technology, gilding arc discharge, while its adsorption capacity was studied with the acid orange II (AO II) solution selected as the target wastewater. Several factors, such as air flow rate, distance between samples and the discharge area, pH of the solution and plasma treating time, were investigated with respect to their effects on properties of the plasma-treated ACF, in terms of texture characteristic, surface chemical compositions and adsorption capacities. The results showed that the specific surface area and pore volume of ACF decreased after the plasma treatment, while the amounts of oxygen-containing functional groups on the surface of ACF increased compared with the raw ACF. Moreover, it was observed that the adsorption capacity of the modified ACF was improved by nearly 20.9 %, which was beneficial to the industrial application.     

Application of novel activated carbon fiber solid-phase, microextraction to the analysis of chlorinated hydrocarbons in water by gas chromatography-mass spectrometry

This paper presents a study on the performance of activated carbon fiber (ACF) used as extraction fiber for solid-phase microextraction (SPME) and its application for analysis of chlorinated hydrocarbons in water. By means of evaluating scanning electron microscope (SEM) images, specific surface area, pore volume, pore distribution, and properties of adsorption and desorption, the optimal active concentration of phosphoric acid has been determined. Coupled with gas chromatograph-mass spectrometry (GC-MS), ACF-SPME is suitable for determination chlorinated hydrocarbons in water with headspace. Experimental parameters such as adsorption and desorption conditions were studied. The optimized method has an acceptable linearity, good precision, with R.S.D. values <10% for each compound. Compared with commercial fibers, ACF has many advantages such as better resistance to organic solvents, better endurance to high temperature and longer lifetime.     

Structurally and chemically heterogeneous nanofibrous nonwovens via electrospinning

Homogeneous nonwovens composed of polymer nanofibers of a given diameter are characterized by structural parameters such as the average pore sizes and internal surfaces as well as by transport properties, which are strongly correlated to the fiber diameter at a given porosity. Such nonwovens are used among others for filter applications, protective clothing or as scaffolds for tissue engineering. A frequent requirement is that, to be able to prepare nonwovens optimised for the specific application, one has to find ways to disrupt this strong correlation allowing independent modification of pore diameter, transport properties and internal surface or to induce local chemical and structural heterogeneities within the nonwoven. The route explored in this paper is based on the electrospinning of heterogeneous nonwovens composed of nanofibers with two different average diameters (by a ratio of up to 10 and more) on the one hand and/or different chemical nature on the other hand. Spinning parameters have been optimised to achieve this goal. In addition, nonwovens composed of fibers with circular cross-section and with ribbon-like cross-section have been prepared.     

活性炭纤维的微孔结构水吸附

测定了两种活性炭纤维（ACF）的氮气、水吸附等温线和XPS,研究了ACF的微孔结构和表面性质,用αs图分析氮吸附等温线获得了ACF的比表面积、微孔容量和微孔径。XPS表明在ACF表面存在多种不同结合状态的氧。水在ACF上的吸附等温线呈V型,具有很大的脱附滞后环。水通过与ACF表面的氧形成氢键发生吸附。ACF表面的初始吸附点多,则在低、中压时的水吸附量就大。     

SO2和NO对ACF低温脱除模拟燃煤烟气中VOC的影响

采用H₂O₂浸渍的方法对活性炭纤维(ACF)进行改性,并利用氮吸附等温线和XPS(X-ray photoelectron spectroscopy)的方法对ACF样品进行表征。通过实验测定改性前后ACF脱除VOC(甲苯作为VOC的代表物)的效果,同时考察二氧化硫(SO₂)和一氧化氮(NO)对ACF脱除甲苯的影响。研究发现,双氧水浸渍改性对ACF的BET表面积和孔容没有影响,但使得ACF样品表面的含氧官能团含量大量增加。实验数据也表明,SO₂和NO对VOC在ACF上的吸附具有抑制作用,且随着两者浓度的增加,抑制作用也增强。 研究还发现,SO₂和NO同时存在比单一的SO₂或NO对VOC在ACF上吸附的抑制作用更为明显。     

Peptide pore accessibility in reversed-phase chromatography

The effect of salt or peptide concentration on peptide porosity (i.e. the porosity accessible to a given peptide) is investigated on six different reversed-phase stationary phases. The peptide porosity is found to increase with the local concentration of negative charges following a saturation-type function within the same porosity boundaries for both cases. This can induce the formation of anti-Langmuirian peaks in non-adsorbing conditions since the local increase of the ionic strength due to the peptide concentration increases the porosity accessible to the peptide. This behavior can be well reproduced by the ideal model of chromatography assuming non-constant porosity. The acetonitrile adsorption isotherm was also measured on all the considered reversed-phase stationary phases. A comparison between the stationary phases shows a correlation between the amount of acetonitrile accumulated in the pores and the reduced pore accessibility for the peptide.     

染料在剑麻基活性碳纤维上吸附速度的研究

本文研究了单组分染料在活性碳纤维上的吸附速度及双组分染料的竞争吸附速度。研究结果表明,不同染料分子在ＳＡＣＦ上吸附速度差异较大,结晶紫的吸附速度比亚甲基蓝或铬蓝黑Ｒ慢行多。亚甲基蓝和铬蓝黑Ｒ双组分共存时,其吸附速度与单组分时的相近,但初始阶段亚甲基蓝的吸附比铬蓝黑Ｒ快得多。由于染料的分子尺寸与ＡＣＦ的微孔大小相近,染料在活性碳纤维上的七染料孤及活怀碳纤维的孔结构密切相关。因此,不同染料分子在ＡＣＦ     

Some remarks on the calculation of the pore size distribution function of activated carbons

Different authors investigated the effects of geometric and energetic heterogeneities on adsorption and on carbon characterization methods. In most theoretical studies carbon structure is modeled as parallel infinite graphite walls that form ideal slit-shaped pores of the fixed widths. In the literature there is the lack of systematic studies showing the influence of pore structural and Lennard-Jones (LJ) potential parameters on the pore-size distribution functions. Moreover, the parameters characterizing the properties of the adsorbed phase and the heterogeneity of the adsorbent surface should be taken into account. The Nguyen and Do method with proposed by us ASA algorithm, were utilized for the assessment of the porosity from the series of almost few thousands numerically generated local adsorption isotherms. The values of the mentioned-above parameters are varied over the wide range (ca. +/-20%) of the reference ones. Different types of the theoretical and experimental adsorption isotherms (nitrogen at 77 K) were taken into account as the global ones. They were related to the mechanism of the primary, secondary or mixed micropore filling. The variations in some above-mentioned parameters have significant effects only for PSDs (and for average pore widths) corresponding to the primary micropore filling mechanism. On the other hand, for the process of the secondary micropore filling, the influence of these parameters (without the BET coefficient for adsorption on a "flat" surface, c(s,B)) is rather insignificant. Nevertheless the differences between local and global adsorption isotherms (in the whole range of relative pressures) the absence of micropores having pore half width equal to ca. 1 nm on PSDs was observed for studied adsorbate-adsorbent systems with exceptions of the strictly microporous adsorbents and/or the low values of c(s,B). Comparison of the experimental data with the generated theoretical isosteric enthalpy of adsorption indicates that the phenomenal uptake observed from experiment can be explained in terms of the reasonable solid-fluid interaction parameters. Therefore, we varied the heterogeneity of the adsorbent surface via the strength and the range of the solid-fluid potential and the parameter c(s,B) in order to reproduce the experimental data of enthalpy of adsorption. Note that similar procedure was applied by Wang and Johnson to reproduce some hydrogen adsorption data measured for carbon nanofibres. The analysis of the obtained results shows that the selection of the values of the parameters of the intermolecular interactions and the quantities characterizing the properties of the adsorbed phase and the heterogeneity of the adsorbent walls for molecular simulations should be made with care and the influence of possible errors should be considered.     

Preparation and characterization of activated carbon fibers supported with silver metal for antibacterial behavior

In this work, the effect of immersion in silver nitrate solution on activated carbon fibers (ACFs) was investigated in relation to adsorption behavior and antibacterial activity of ACFs supported with silver (ACF/Ag). The pore and surface properties were studied in terms of BET volumetric measurement with nitrogen adsorption, X-ray diffraction (XRD), and scanning electron microscopy (SEM). The antibacterial activities of ACF/Ag were studied in broth dilution tests against Staphylococcus aureus (S. aureus) and Escherichia coli (E. coli) from a point of view of water purification. As an experimental result, the silver content of ACF/Ag increased with increasing concentration of silver nitrate. It was found that the micropore structure slightly decreased as the silver nitrate concentration increased. Otherwise, it was revealed that the ACF/Ag possessed a strong antibacterial activity and an inhibitory effect for the growing of E. coli and S. aureus, respectively. Silver content on ACF/Ag decreased rapidly because of rough morphology of silver particles in water erosion.