具有染料选择吸附性的衍生于沸石咪唑酯骨架-67的NiCo-层状双氢氧化物设计与合成

以沸石咪唑类金属有机骨架(ZIF-67)为模板合成了一种新型的中空吸附剂NiCo-LDH@ZIF-67,该吸附剂对甲基橙具有良好的选择吸附性以及可循环性。 通过扫描电子显微镜(SEM)、透射电子显微镜(TEM)、X射线粉末衍射仪(XRD)、红外光谱、电子能谱和氮气吸附-脱附等手段对样品进行了表征。 研究了溶液的pH值、甲基橙的初始浓度以及染料与吸附剂作用时间对NiCo-LDH@ZIF-67吸附性能的影响。 结果表明,该吸附剂对甲基橙的吸附动力学符合准二级动力学模型,且吸附等温线符合朗缪尔方程。 当pH值等于4, 吸附时间15 min,吸附剂用量为2400 mg/L时,该吸附剂对甲基橙的最大吸附量可达1766 mg/g,高于之前文献报道的类似吸附剂。 此外,NiCo-LDH@ZIF-67能从甲基橙和亚甲基蓝的混合溶液中选择性吸附甲基橙。     

具有染料选择吸附性的衍生于沸石咪唑酯骨架-67的NiCo-层状双氢氧化物设计与合成（英文）

以沸石咪唑类金属有机骨架(ZIF-67)为模板合成了一种新型的中空吸附剂NiCo-LDH@ZIF-67,该吸附剂对甲基橙具有良好的选择吸附性以及可循环性。通过扫描电子显微镜(SEM)、透射电子显微镜(TEM)、X射线粉末衍射仪(XRD)、红外光谱、电子能谱和氮气吸附-脱附等手段对样品进行了表征。研究了溶液的pH值、甲基橙的初始浓度以及染料与吸附剂作用时间对NiCo-LDH@ZIF-67吸附性能的影响。结果表明,该吸附剂对甲基橙的吸附动力学符合准二级动力学模型,且吸附等温线符合朗缪尔方程。当pH值等于4,吸附时间15 min,吸附剂用量为2400 mg/L时,该吸附剂对甲基橙的最大吸附量可达1766 mg/g,高于之前文献报道的类似吸附剂。此外,NiCo-LDH@ZIF-67能从甲基橙和亚甲基蓝的混合溶液中选择性吸附甲基橙。     

锌镍铝水滑石微球的制备及吸附性能

以Zn(NO_3)_2·6H_2O、Ni(NO_3)_2·6H_2O、Al(NO_3)_3·9H_2O和尿素为原料,采用一步水热法制备分散性良好的三元锌镍铝水滑石(ZnNiAl-LDHs)微球。通过X射线衍射(XRD)、傅里叶转换红外光谱(FTIR)、场发射扫描电镜(FESEM)、透射电镜(TEM)和氮气吸附-脱附等测试手段对样品的结构和形貌进行表征,并比较ZnNiAl-LDHs和ZnAl-LDHs对甲基橙(MO)的吸附性能。结果表明,ZnNiAl-LDHs是由纳米片组成、具有3D结构的微球,粒径为1~2.5μm,比表面积为156m2·g~(-1),远大于ZnAl-LDHs的比表面积38m2·g~(-1);ZnNiAl-LDHs和ZnAl-LDHs对甲基橙的饱和吸附量分别为329.60和143.47mg·g~(-1),ZnNiAl-LDHs表现出更强的吸附能力,其吸附等温线和吸附动力学分别符合Langmuir等温线模型和准二级动力学模型。     

Fe3O4@(SDS-HTlc)纳米复合物的制备及对甲基橙的吸附

采用离子交换法制备了具有核-壳结构的磁性十二烷基硫酸钠改性类水滑石Fe_3O_4@(SDSHTlc)纳米复合物,并利用透射电镜、粉末X-射线衍射、红外光谱、电感耦合等离子体发射光谱、元素分析等对其进行了表征。研究了Fe_3O_4@(SDS-HTlc)对甲基橙的吸附动力学和热力学。结果表明,Fe_3O_4@(SDSHTlc)对甲基橙有较好吸附效果,吸附动力学曲线符合准二级动力学方程;吸附等温线符合线性方程,吸附量随体系p H的增大和温度的升高均降低。在外部磁场下,30s内可从水溶液中分离出Fe_3O_4@(SDS-HTlc),这为去除水中疏水染料提供了简单的一步吸附处理方法。     

ZnO/C纳米球的亚甲基蓝单吸附特性:平衡、动力学及机理（英文）

采用电弧放电法制备了Zn O/C纳米球,利用FESEM、XRD和N2吸附/脱附测试进行了表征。在避光条件下研究了复合材料对亚甲基蓝的吸附性能。研究结果表明,随着亚甲基蓝的浓度及接触时间的增长吸附量明显上升,在吸附时间为150 min时达到吸附平衡。采用Langmuir、Freundlich及Temkin等温吸附模式对吸附平衡进行了研究。结果表明,吸附等温线符合Langmuir等温吸附模式,单层吸附饱和容量可达188.68 mg·g-1。利用动力学模型、内扩散模型和外扩散速率控制模型拟合实验数据,拟合数据表明其动力学符合伪二级动力学模型;内扩散机理不是吸附速率的唯一限制机理,亚甲基蓝的总吸附速率受膜扩散控制。     

纳米氢氧化铝-聚丙烯酰胺复合絮凝剂对镉离子的吸附研究

采用响应面法对纳米氢氧化铝-聚丙烯酰胺复合絮凝剂吸附Cd(II)过程进行了拟合和优化,分别以pH值、温度和Cd(II)浓度为自变量,研究了其对响应值镉离子最大吸附量的影响,并通过吸附动力学方程和吸附等温线数据对吸附机理进行了探讨。结果表明,采用响应面法对pH值、温度和Cd(II)浓度3个自变量进行优化后得出最大吸附量为79.07mg/g,其最优条件为:pH 6.35,镉离子浓度91.36mg/L,温度50℃;氢氧化铝-聚丙烯酰胺对Cd(II)的吸附在120min内达到平衡,且吸附动力学数据符合准二级动力学模型,表明吸附过程包含化学吸附;吸附速率的控制步骤是吸附脱附平衡步骤;吸附等温线数据与Langmuir吸附等温模型相一致,表明镉离子在氢氧化铝-聚丙烯酰胺表面形成的是单层吸附层。     

改性埃洛石材料的制备及其对亚甲基蓝吸附行为的研究

使用硅烷偶联剂KH550改性埃洛石纳米管获得改性材料HNTs-APTS,并对其吸附亚甲基蓝的行为进行研究。利用傅立叶变换红外光谱仪(FTIR)、X-衍射仪(XRD)对改性前后的埃洛石进行表征。考察了吸附时间和温度对吸附过程的影响,并采用Lagrange准二级动力学方程、Langmuir等温线方程及Freundlich等温线方程对实验数据进行拟合。结果表明,KH550成功负载到埃洛石表面;改性后材料的吸附能力大大提高。改性埃洛石对亚甲基蓝的吸附约在60 min达平衡,最大吸附容量为21.66 mg/g。其吸附过程符合准二级动力学方程,热力学较好地符合Langmuir等温线方程,且吸附过程为自发吸热,升高温度有利于吸附的进行。改性材料可重复再生6次,具有良好的再生性能,可在工业处理亚甲基蓝废水中使用。     

ZnO/C纳米球的亚甲基蓝单吸附特性:平衡、动力学及机理

采用电弧放电法制备了ZnO/C纳米球,利用FESEM、XRD和N₂吸附/脱附测试进行了表征。在避光条件下研究了复合材料对亚甲基蓝的吸附性能。研究结果表明,随着亚甲基蓝的浓度及接触时间的增长吸附量明显上升,在吸附时间为150 min时达到吸附平衡。采用Langmuir、Freundlich及Temkin等温吸附模式对吸附平衡进行了研究。结果表明,吸附等温线符合Langmuir等温吸附模式,单层吸附饱和容量可达188.68 mg·g^-1。利用动力学模型、内扩散模型和外扩散速率控制模型拟合实验数据,拟合数据表明其动力学符合伪二级动力学模型;内扩散机理不是吸附速率的唯一限制机理,亚甲基蓝的总吸附速率受膜扩散控制。     

ZnO/C纳米球的亚甲基蓝单吸附特性:平衡、动力学及机理

采用电弧放电法制备了ZnO/C纳米球,利用FESEM、XRD和N₂吸附/脱附测试进行了表征。在避光条件下研究了复合材料对亚甲基蓝的吸附性能。研究结果表明,随着亚甲基蓝的浓度及接触时间的增长吸附量明显上升,在吸附时间为150 min时达到吸附平衡。采用Langmuir、Freundlich及Temkin等温吸附模式对吸附平衡进行了研究。结果表明,吸附等温线符合Langmuir等温吸附模式,单层吸附饱和容量可达188.68 mg·g^-1。利用动力学模型、内扩散模型和外扩散速率控制模型拟合实验数据,拟合数据表明其动力学符合伪二级动力学模型;内扩散机理不是吸附速率的唯一限制机理,亚甲基蓝的总吸附速率受膜扩散控制。     

三聚氰胺功能化多孔有机聚合物的合成及其对甲基橙的吸附性能

首先以对三联苯(TP)和对苯二甲酰氯(TC)为单体合成了酮基聚合物前体(TP-TC),而后基于席夫碱反应将三聚氰胺(MA)与之交联得到胺功能化的多孔有机聚合物TP-TC-MA。通过扫描电镜(SEM)、透射电镜(TEM)、傅里叶变换红外光谱(FT-IR)、X射线衍射(XRD)、氮气吸附-脱附(BET)以及零电荷点(pH_pzc)的测定等手段对合成的多孔有机聚合物进行表征。以染料废水中典型的阴离子染料甲基橙为研究对象,研究了TP-TC-MA对其吸附行为,并探讨了吸附机制。利用紫外-可见分光光度计(UV-Vis)得出目标污染物的紫外吸收光谱标准曲线,标准曲线拟合相关系数(R²)为0.999。结果表明,TP-TC-MA由于具有高比表面积(708.5 m²/g)和总孔体积(0.556 cm³/g)以及丰富的含氮基团,对阴离子染料甲基橙表现出优异的吸附性能。TP-TC-MA对水中甲基橙的吸附动力学符合准二级动力学方程,吸附平衡数据可以采用Langmuir等温吸附模型描述。经由Langmuir等温吸附模型计算得到的理论最大吸附容量为156.3 mg/g。选择性实验结果表明,TP-TC-MA对阴离子染料甲基橙具有更强的吸附作用,吸附作用机理可归结为静电相互作用、氢键和π-π相互作用等。在重复使用5次之后,TP-TC-MA对甲基橙仍保持90%以上的去除率,表明材料具有良好的稳定性和重复利用性,在染料废水处理中具有很好的应用前景。     

氨水诱导硅核自组装制备介孔SiO_2

在无模板剂的条件下,通过控制氨水用量,利用正硅酸乙酯水解制备了粒径约20 nm的SiO2初级粒子;随后用过量氨水诱导SiO2初级粒子交联生长,得到孔径在10~50 nm、孔容达2.05 cm3.g-1的介孔SiO2;考察了介孔SiO2的吸附性能.结果表明,所制备的介孔SiO2具有优良的吸附性能.     

磁性有序介孔炭的制备及药物吸附行为研究

采用纳米共铸法将磁性纳米粒子包埋到有序介孔炭的骨架中, 制成含有磁性纳米粒子的有序介孔炭(Fe/OMCs). 实验通过氮气吸附、扫描电镜、X射线衍射、磁性测试等手段对Fe/OMCs进行了系统的表征. 研究表明, Fe/OMCs基本保持了有序介孔结构, 磁性粒子在材料中以纳米α-Fe粒子的形式存在, 并且具有超顺磁特性. 盐酸四环素(TH)在Fe/OMCs上的吸附研究表明, Fe/OMCs的介孔表面积和介孔孔容是决定TH吸附量的关键因素. 脱附动力学研究表明, Fe/OMCs的孔尺寸是影响脱附速率的关键因素, 孔径越大, TH的脱附速率就越大.     

Mesoporous nickel oxide nanowires: hydrothermal synthesis, characterisation and applications for lithium-ion batteries and supercapacitors with superior performance

Mesoporous nickel oxide nanowires were synthesized by a hydrothermal reaction and subsequent annealing at 400?°C. The porous one-dimensional nanostructures were analysed by field-emission SEM, high-resolution TEM and N(2) adsorption/desorption isotherm measurements. When applied as the anode material in lithium-ion batteries, the as-prepared mesoporous nickel oxide nanowires demonstrated outstanding electrochemical performance with high lithium storage capacity, satisfactory cyclability and an excellent rate capacity. They also exhibited a high specific capacitance of 348?F?g(-1) as electrodes in supercapacitors.     

Surface Modifications of Halloysite Nanotubes with Superparamagnetic Fe3O4 Nanoparticles and Carbonaceous Layers for Efficient Adsorption of Dyes in Water Treatment

Surface modification of halloysite nanotube(HNT) with in situ grown Fe₃O₄ nanoparticles and carbonaceous layers introduced by a hydrothermal carbonization process of glucose has been achieved. Structure and morphology investigations demonstrate that iron oxide nanoparticles are uniformly anchored on the halloysite and prevent the aggregations of halloysite and carbon, forming a protective layer that stabilizes and improves the property of HNT/Fe₃O₄/C nanocomposite. Magnetism characterization proves the superparamagnetic behavior of HNT/Fe₃O₄/C hybrid at room temperature, which makes it easily separated from dye solution under an external magnetic field. Exploration of adsorption ability demonstrates that the maximum adsorption capacity of the as-prepared HNT/Fe₃O₄/C nanocomposite for methylene blue(MB) is about twice and 1.5 times those of HNT/Fe₃O₄ and HNT according to Langmuir equation, respectively. The adsorption behavior investigations indicate that HNT/Fe₃O₄/C hybrid has a heterogeneous structure and shows a non-ideal monolayer adsorption that fits the Redlich-Peterson isotherm, and the adsorption process follows a pseudo-second-order kinetic model. Therefore, the as-prepared HNT/Fe₃O₄/C hybrid is a fast, separatable and superparamagnetic adsorbent with a good adsorption ability, demonstrating great potential in the application of water treatment.     

Self-assembling and size-selective synthesis of Ni and NiO nanoparticles embedded in ordered mesoporous carbon and polymer frameworks

We demonstrate the self-assembling and size-selective synthesis of uniform and highly dispersed Ni or NiO nanoparticles with diameters below 12 nm embedded in ordered mesoporous carbon or polymer frameworks. Self-assembly is induced by evaporation of the solvent from a mixture of metal-containing liquid crystalline (LC) mesophases of triblock copolymer and transition metal nitrate hydrate, and the carbon source is low-polymerized phenolic resol. Characterization by XRD, N(2) sorption isotherms, TEM, HRSEM, ICP-AES, TG, and XPS techniques has indicated an ordered 2D hexagonal mesostructure, high surface areas between 524 and 721 m(2) g(-1), uniform pore sizes of about 4.0 nm, large pore volumes ranging from 0.34 to 0.58 cm(3) g(-1), and metal contents ranging from 0.6 to 10.0 wt%. There is a high degree of dispersion, and a small size of nanoparticles throughout the whole framework, without aggregation outside of the pores due to the confinement effect of the mesoporous ordered matrix. The mesoporous solids show excellent adsorption properties for dyes and permit an easy magnetic separation procedure. This method is expected to be applicable to other mesoporous transition metal(oxide)-containing carbon catalysts.     

Chemical and biological treatment of waste water with a novel silver/ordered mesoporous alumina nanocomposite

One of the serious problems in the present century is chemical and biological pollution of the environment. Nanocomposites are multiphase solid materials that have been used as adsorbent of pollutants such as dyes, pesticides, anions and etc. in the last decades. In this study, a novel nanocomposite including silver nanoparticles and ordered mesoporous alumina (OMA) has been synthesized and used for the removal of dyes pollutants (methyl orange, bromothymol blue and reactive yellow) from aqueous solution. The characterization of synthesized nanocomposite has been performed by TEM, N₂ adsorption/desorption, XRD and energy dispersive X-ray spectroscopy analysis. The adsorption kinetic and equilibrium data have been obtained by UV–vis spectroscopy. The results show that the silver/OMA nanocomposite (Ag/OMA nanocomposite) is good adsorbent for the removal of anionic dyes from aqueous solution, and also this nanocomposite has a biocidal action against both Gram-negative and Gram-positive bacteria.     

Mixed phase Fe2O3/Mn3O4 magnetic nanocomposite for enhanced adsorption of methyl orange dye: Neural network modeling and response surface methodology optimization

In this research, a novel magnetic mesoporous adsorbent with mixed phase of Fe₂O₃/Mn₃O₄ nanocomposite was prepared by a facile precipitating method and characterized extensively. The prepared nanocomposite was used as adsorbent for toxic methyl orange (MO) dye removal from aqua matrix considering its high surface area (178.27 m²/g) with high saturation magnetization (23.07 emu/g). Maximum dye adsorption occurs at solution pH 2.0 and the electrostatic attraction between anionic form of MO dye molecules and the positively charged nanocomposite surface is the main driving force behind this adsorption. Response surface methodology (RSM) was used for optimizing the process variables and maximum MO removal of 97.67% is obtained at optimum experimental condition with contact time, adsorbent dose and initial MO dye concentration of 45 min, 0.87 g/l and 116 mg/l, respectively. Artificial neural network (ANN) model with optimum topology of 3–5–1 was developed for predicting the MO removal (%), which has shown higher predictive ability than RSM model. Maximum adsorption capacity of this nanocomposite was found to be 322.58 mg/g from Langmuir isotherm model. Kinetic studies reveal the applicability of second‐order kinetic model with contribution of intra‐particle diffusion in this process.     

介孔Ni/CaO-ZrO2纳米复合物催化甲烷和二氧化碳重整

采用溶胶-凝胶法制备了一种具有高热稳定性的介孔Ni/CaO-ZrO2纳米复合物.此纳米复合物在甲烷/二氧化碳重整中表现出较高的活性和稳定性,且经连续运行50h后,其催化活性没有明显降低,稳定性显著高于Ni/Al2O3或Ni/SiO2负载型催化剂.这是由于反应过程中纳米Ni颗粒尺寸被有效稳定以及碱性组分CaO的存在,催化剂中相互嵌合的Ni,ZrO2和CaO的颗粒尺寸均为10nm左右,堆积形成了海绵状的介孔结构.CaO的存在使催化剂具有较强的碱性,促进了反应物CO2的化学吸附和解离.     

Ni2P/SBA-15催化剂的结构及加氢脱硫性能

以硝酸镍为镍源, 磷酸氢二铵为磷源, 介孔分子筛SBA-15为载体, 用共浸渍法制备了含磷化镍前驱体的样品, 然后在氢气流中采用程序升温还原法, 制备了Ni2P质量分数为5%-40%的Ni2P/SBA-15催化剂. 用X射线衍射(XRD)、N2吸附脱附、透射电子显微镜(TEM)、傅立叶变换红外光谱(FTIR)等分析测试技术对催化剂的结构进行了表征, 以噻吩和二苯并噻吩(DBT)为模型化合物, 在微型固定床反应器上对催化剂的加氢脱硫(HDS)性能进行了评价. 结果表明, Ni2P/SBA-15催化剂中SBA-15 的介孔结构依然存在, 活性组分Ni2P具有良好的分散性, 但随Ni2P含量的增加, 催化剂的比表面积、孔容和孔径均有明显减小. 当反应温度为320 ℃时, Ni2P含量为15%-25%(w)的催化剂就具有很好的加氢脱硫催化性能; 反应温度在360 ℃以上时, 所有催化剂都具有优异的深度脱硫催化性能. Ni2P/SBA-15催化剂对二苯并噻吩的加氢脱硫(HDS)主要以直接脱硫机理(DDS)进行.     

CO2 reforming of methane over nickel catalysts supported on nanocrystalline MgAl2O4 with high surface area

In this paper dry reforming of methane (DRM) was carried out over nanocrystalline MgAl2O4-supported Ni catalysts with various Ni loadings. Nanocrystalline MgAl2O4 spinel with high specific surface area was synthesized by a co-precipitation method with the addition of pluronic P123 triblock copolymer as surfactant, and employed as catalyst support. The prepared samples were characterized by X-ray diffraction (XRD), N2 adsorption, H2 chemisorption, temperature-programmed reduction (TPR), temperature-programmed oxidation (TPO), temperature- programmed desorption (TPD) and transmission and scanning electron microscopies (TEM, SEM) techniques. The obtained results showed that the catalyst support has a nanocrystalline structure (crystal size: about 5 nm) with a high specific surface area (175 m2 g-1) and a mesoporous structure. Increasing in nickel content decreased the specific surface area and nickel dispersion. The prepared catalysts showed high catalytic activity and stability during the reaction. SEM analysis revealed that whisker type carbon deposited over the spent catalysts and increasing in nickel loading increased the amount of deposited carbon. The nickel catalyst with 7 wt% of nickel showed the highest catalytic activity.