纯相钙铝层状双氢氧化物对磷的吸附特性

采用乙醇辅助液相共沉淀法制备了纯相Ca-Al-LDH层状双金属氢氧化物,考察了Ca-Al-LDH的投加量、吸附时间、pH值、无机电解质(Na₂CO₃ ,KCl ,Na₂SO₄,KNO₃)和温度等因素对磷吸附的影响,结果表明,纯相Ca-Al-LDH对磷酸根离子具有很好的吸附性能,最大饱和吸附量可达160.78 mg/g,当pH值为5.1、温度为45 ℃、吸附时间为600 min、LDH投加量为0.6 g/L、磷初始浓度为80 mg/L时,磷的去除率高达95.88%;无机阴离子会抑制磷在吸附剂上的吸附,当Cl^-浓度从2.5 g/L升高到25 g/L时,Ca-Al-LDH对磷酸盐的最大饱和吸附量从69.96 mg/g降至53.18 mg/g,降低了23.99%;当SO₄^2-浓度从2.5 g/L升高到25 g/L时,Ca-Al-LDH对磷酸盐的最大饱和吸附量降低了24.79%,其它无机阴离子对磷在吸附剂上的吸附也有一定的影响。 Ca-Al-LDH对水中磷的吸附符合二级动力学方程和Langmuir等温模型。 采用扫描电子显微镜、傅里叶变换红外光谱仪和X射线衍射仪等技术手段对制备的纯相Ca-Al-LDH及其吸附磷酸根后的产物进行表征,揭示了Ca-Al-LDH对磷酸根的吸附可能是静电吸引、化学吸附和阴离子插层等过程协同作用的吸附机理。     

改性茶渣对酸性橙Ⅱ的吸附性能

染料废水由于结构复杂、色度高、难降解成为废水处理的一大难题。吸附法由于操作简单、效果好等优点成为处理印染废水的重要方法之一。本文采用磷酸、过氧化氢改性的废弃茶渣作为一种价格低廉、来源丰富、环保无污染的吸附材料,以酸性橙Ⅱ染料废水作为研究对象,从吸附动力学、等温吸附、pH值的影响等方面探讨改性茶渣对酸性橙Ⅱ的吸附性能。实验结果表明,改性茶渣具有粗糙多孔的表面结构。25℃,pH值为2左右时,磷酸、过氧化氢处理的茶渣对酸性橙Ⅱ的吸附量分别为49.24mg/g和49.03mg/g。随着温度升高,改性茶渣对酸性橙Ⅱ的吸附量增大,吸附过程符合Freundlich等温方程。随着吸附时间的增加,吸附量逐渐增大至平衡,吸附过程符合拟一级动力学方程。pH值增大,改性茶渣对酸性橙Ⅱ的吸附量降低,在pH值为2.0时吸附效果最佳。     

Mg/Fe类水滑石的磷酸根吸附性能及吸附机理

采用共沉淀法成功制备了Mg/Fe类水滑石(Mg/Fe-hlc),并研究了其对废水中磷酸根的吸附性能及吸附机理。研究结果表明:制备的Mg/Fe-hlc具有典型的类水滑石结构和较大的比表面积(156.7 m~2·g~(-1));Mg/Fe-hlc对磷酸根的吸附动力学过程符合准二级动力学模型;Langmuir和Tempkin方程都可以很好地拟合Mg/Fe-hlc对磷酸根的等温吸附数据,Langmuir方程拟合得到的最大吸附量可达47.38 mg·g~(-1);共存阴离子NO_3~-、Cl~-和SO_4~(2-)对磷吸附性能的影响很小;通过分析吸附磷酸根前后的Mg/Fe-hlc的结构和织构性质以及表面官能团变化,并结合溶液pH对磷酸根吸附影响实验结果,发现静电相互作用、配体交换和阴离子交换是Mg/Fe-htl吸附磷酸根的三种主要机制。     

新型吸附剂偏磷酸铈对铀酰的吸附性能研究

研究新型吸附剂偏磷酸铈对铀酰离子的吸附行为。分别考察了溶液的pH值、温度、接触时间和铀酰离子初始浓度对偏磷酸铈吸附铀酰离子的影响;通过动力学、热力学以及吸附等温线初步研究了吸附机理;最后探究了共存离子和富里酸对吸附的影响。当溶液的pH值为5、温度为30℃、接触时间为60min、铀酰初始浓度为10~(-3)mol/L时为最佳吸附条件,最大吸附量可达到261.78mg/g;动力学研究表明,偏磷酸铈对铀酰离子吸附行为符合准二级动力学方程;Langmuir吸附等温线模型可以更准确的描述铀酰离子在偏磷酸铈上的吸附过程,说明此吸附过程为单分子层吸附;热力学研究表明,偏磷酸铈对铀酰离子的吸附属于吸热反应,反应自发进行,高温促进吸附行为。     

希夫碱型木质素基吸附材料的制备及其对Pb~(2+)吸附性能研究

以乙酸木质素为原料,通过曼尼希胺化反应和希夫碱反应制备希夫碱型木质素基离子吸附材料(SLA),利用红外光谱、核磁共振氢谱和元素分析等手段对SLA的结构进行表征。考察了溶液pH值、吸附剂用量和离子溶液初始浓度等因素对SLA吸附性能的影响。结果表明,在pH=5.0、吸附剂用量2.0g/L、Pb~(2+)溶液浓度200mg/L条件下,SLA对Pb~(2+)具有较高的吸附量(65.45mg/g)和良好的吸附选择性。研究结果表明,SLA对Pb~(2+)的等温吸附过程符合Freundlich等温吸附模型,存在非均匀多层吸附现象;SLA对Pb~(2+)的吸附动力学过程符合准二级吸附动力学模型,表明SLA对Pb~(2+)的吸附作用主要为化学吸附。     

SDS改性沸石对碱性品红的吸附性能研究

通过静态实验探讨了表面活性剂十二烷基硫酸钠（SDS）改性沸石吸附碱性品红的影响因素。实验结果表明在投入量为8 g/L、吸附时间为45 min、p H值为6、温度为25℃时,对初始质量浓度100 mg/L碱性品红溶液的去除率可达到96.16%,吸附量为12.02 mg/g;SDS改性沸石吸附碱性品红的吸附性能符合Langmuir型吸附等温线和一级反应动力学模型的特征;热力学分析结果表明,吸附符合自发吸热过程。     

一种磷酸根-羧甲基葡甘聚糖锆凝胶球的吸附性能

用氧氯化锆溶液交联羧甲基葡甘聚糖制得新型吸附材料—羧甲基葡甘聚糖锆凝胶球。探究了凝胶球对磷酸根的吸附性能,考察了羧甲基葡甘聚糖浓度、氧氯化锆浓度、吸附时间、pH值、温度和磷酸根浓度对吸附的影响。结果表明:298K时,凝胶球对磷酸根的吸附9h达平衡,当CMKGM和氧氯化锆浓度均为2.0%,磷酸根初始浓度为600mg·L-1,pH为2.5时,吸附量为186.65mg/g。利用Langmuir方程拟合实验数据,发现该方程适合于所研究的吸附体系。该体系为吸热体系,升温有利于吸附。     

钙蒙脱土吸附镧的影响因素及其应用

以钙基蒙脱土(Ca-MMT)为载体,研究其对镧(La)的吸附。 采用X射线衍射仪(XRD)、扫描电子显微镜(SEM)和元素mapping分析、傅里叶红外光谱(FT-IR)、BET、X射线荧光光谱分析(XRF)对其晶型结构、表面形态、比表面积、化学结构进行表征,考察了La的初始浓度、pH值、温度对Ca-MMT吸附镧性能的影响,考察了载镧钙基蒙脱土(Ca-MMT@La)的除磷效果。 结果表明:Ca-MMT投入量为10 g/L时,Ca-MMT的平衡吸附量随镧的初始浓度增加而增大,最大吸附量为49.62 mg/g;随着pH值增大,吸附能力增强,pH=6时为最佳pH吸附镧条件,吸附量为38.36 mg/g;随温度的升高,其吸附量先下降再上升,20 ℃吸附能力最大,吸附量为41.23 mg/g。 Langmuir等温吸附方程推断其吸附属于单分子层吸附。 Ca-MMT不具有吸附磷效果,而Ca-MMT@La对磷酸根有很强的吸附能力,吸附量为7.24 mg/g,除磷率为72.41%,其除磷率随含镧量增大而增大。     

磷酸化黄原胶/氧化石墨烯的合成及其对铀的选择性吸附

以氧化石墨烯(GO)为基体,黄原胶(XG)为交联剂,磷酸(P)为修饰剂制备了磷酸功能化黄原胶/氧化石墨烯凝胶(P-XG/GO),并应用于铀的选择性吸附。扫描电子显微镜(SEM)、X射线衍射(XRD)、傅里叶变换红外光谱(FT-IR)、Zeta电势分析等技术表明GO的交联和磷酸化成功。系统研究了溶液pH值、铀初始浓度、吸附时间和温度等因素的影响,得到了适宜吸附条件。吸附数据用Langmuir等温线模型拟合良好,最大吸附能力为495.05 mg/g。与准一级动力学模型相比,准二级动力学模型更好地拟合了吸附过程。     

乙二胺硅胶复合材料对Zn2+的吸附特性

以γ-氯丙基三氯硅烷为偶联剂,将乙二胺偶合接枝在硅胶表面,合成对锌离子具有吸附作用的乙二胺硅胶复合材料（EDA/SiO2）,考察了Zn2+溶液pH值、初始浓度、吸附温度和吸附时间等因素对复合材料吸附性能的影响。 结果表明,在研究的溶液浓度及温度范围内,Zn2+溶液pH值对EDA/SiO2的吸附量影响显著,吸附的最佳pH值范围在3.0~5.5;Zn2+的吸附平衡数据符合Langmuir吸附模型,热力学数据显示,EDA/SiO2对Zn2+的吸附行为为一吸热且自发进行的过程,升高温度有利于吸附,并对此吸附行为作了解释;吸附动力学数据可用拟二级吸附动力学方程描述,得到的吸附速率常数与溶液初始浓度有关。     

Adsorption of acridine yellow G from aqueous solutions using functionalized graphene nanoplatelets/modified polybutadiene hybrid composite

This paper presents an analysis of adsorption of acridine yellow G (AYG) from aqueous solutions through the use of functionalized grapheme nanoplatelets/modified polybutadiene hybrid composite (FGNPs/MPB). The adsorption of AYG onto FGNPs/MPB was investigated based on the AYG concentration, pH, contact time, temperature, and adsorbent dose. A maximum adsorption capacity was obtained at a pH of 7 (23.7 mg/g), an adsorbent dose of 1.0 g/L (20.8 mg/g), and an initial AYG concentration of 28.5 mg/L (16.9 mg/g). The value of q_e of FGNPs/MPB increases with an increase in temperature from 293 to 323 K. Equilibrium isotherm data were analyzed using the Langmuir and Freundlich isotherm models. The Langmuir model best describes the adsorption processes of AYG, which showed that the monolayer adsorption capacity of FGNPs/MBP is 22.9 mg/g. The pseudofirst-order, pseudosecond-order, and intraparticle diffusion models were used to study the kinetics of the AYG adsorption onto FGNPs/MPB. The pseudosecond-order model better described kinetic data for the adsorption of AYG onto FGNPs/MPB. Thermodynamic parameters, such as the Gibbs free energy, enthalpy, and entropy, indicated that the AYG adsorption onto FGNPs/MPB was spontaneous feasible, and endothermic.     

焙烧层状氢氧化镁铝对水中氟离子的吸附性能

研究了焙烧层状氢氧化镁铝(CLDH)对水中氟离子的吸附性能,考察了焙烧温度、吸附时间、吸附剂用量、溶液pH值等条件对吸附的影响.发现在较宽的pH(5.5～9.5)值范围内,CLDH对水中氟离子具有良好的吸附能力,室温下0.2gCLDH可将50mL浓度为15mg/L氟离子溶液处理为符合含氟标准的饮用水.吸附平衡符合Langmuir方程,在60min内达到饱和吸附,室温下饱和吸附量为22.64 mg/g.吸附饱和后的CLDH焙烧再生,循环使用5次后饱和吸附量为10.37 mg/g.     

碳纳米管对苯胺的吸附行为

碳纳米管有较大的比表面,有利于用作吸附剂。当前研究主要集中在对气体,尤其是对H2气的吸附。近年来,也有人将碳纳米管应用于环境保护领域,Long等使用碳纳米管除去二恶英,Li等用碳纳米管吸附溶液中的Cd^2 都取得了满意的效果。苯胺类化合物是国家严格控制的一类污染物,使用碳纳米管对苯胺的吸附研究尚未见报道。     

亚铁氰化铜-聚丙烯酰胺/羧甲基纤维素/石墨烯复合水凝胶的制备及铷吸附性能

铷是一种稀贵的碱金属,具有很高的经济价值和广阔应用前景,从卤水中有效提取铷具有重要意义。通过热引发聚合法合成水凝胶基质（聚丙烯酰胺/羧甲基纤维素/氧化石墨烯水凝胶,PCG）固定亚铁氰化铜（KCuFC）,制备了一种新型的铷（Rb⁺）吸附剂（KCuFC-PCG）。采用物理化学方法对KCuFC-PCG的结构和性质进行了表征。通过批量吸附实验,研究了pH值、吸附时间、Rb⁺初始质量浓度、温度和竞争离子对吸附的影响。结果表明,KCuFC-PCG吸附剂在pH值（5～9）范围内表现出良好的吸附能力,pH=8时表现最佳;在Rb⁺质量浓度为5 mg/L,pH=8,吸附6 h达到吸附平衡,KCuFC-PCG的对Rb⁺的吸附量为89.12 mg/g;动力学行为可用准二级动力学模型来描述,表明化学吸附为速率控制步骤;吸附过程符合Langmuir等温吸附模型,为单分子层吸附,最大吸附量为258.4 mg/g。以0.2 mol/L NH₄Cl作为解吸剂,解吸3 h,解吸率为77%。     

Surface and biological activity of sophorolipid molecules produced by Wickerhamiella domercqiae var. sophorolipid CGMCC 1576

The ion-imprinted magnetic chitosan resins (IMCR) prepared using U(VI) as a template and glutaraldehyde as a cross-linker showed higher adsorption capacity and selectivity for the U(VI) ions compared with the non-imprinted magnetic chitosan resins (NIMCR) without a template. The results showed that the adsorption of U(VI) on the magnetic chitosan resins was affected by the initial pH value, the initial U(VI) concentration, as well as the temperature. Both kinetics and thermodynamic parameters of the adsorption process were estimated. These data indicated an exothermic spontaneous adsorption process that kinetically followed the second-order adsorption process. Equilibrium experiments were fitted in Langmuir, Freundlich, and Dubinin-Radushkevich adsorption isotherm models to show very good fits with the Langmuir isotherm equation for the monolayer adsorption process. The monolayer adsorption capacity values of 187.26 mg/g for IMCR and 160.77 mg/g for NIMCR were very close to the maximum capacity values obtained at pH 5.0, temperature 298 K, adsorbent dose 50 mg, and contact time 3 h. The selectivity coefficient of uranyl ions and other metal ions on IMCR indicated an overall preference for uranyl ions. Furthermore, the IMCR could be regenerated through the desorption of the U(VI) ions using 0.5 M HNO(3) solution and could be reused to adsorb again.     

盾构渣土基碳复合陶粒的制备及除磷性能

以固体废弃物地铁盾构渣土、稻草秸秆和氧化镁为主要原料,通过烧结法制备了一种盾构渣土基碳复合陶粒。考察了陶粒吸附磷的主要影响因素及平衡吸附量,并采用模型对实验数据进行拟合分析。结果表明,当盾构渣土、稻草秸秆粉末和氧化镁质量比为7∶2∶1,在最佳烧结条件700℃烧结可得到除磷性能最佳的陶粒。当吸附pH=6.3时,陶粒具有较高的磷吸附性能。吸附在12 h内基本能达到吸附平衡,该过程适合准二级动力学方程。盾构渣土基碳复合陶粒对磷酸盐的吸附符合Temkin等温模型,随温度升高吸附量逐渐增大,40℃下最大吸附量为12.76 mg/g。热力学参数ΔH=5.64 k J/mol0,ΔS=8.00 J/(K·mol)0,ΔG=3.16 k J/mol0,呈吸热、非自发的热力学特征,陶粒吸附磷后可通过2.0 mol/L的氢氧化钠溶液重新解吸回收。     

Removal of Reactive Yellow 84 from aqueous solutions by adsorption onto hydroxyapatite

The adsorption of a reactive dye, Reactive Yellow 84, from aqueous solution onto synthesized hydroxyapatite was investigated. The experiments were carried out to investigate the factors that influence the dye uptake by the adsorbent, such as the contact time under agitation, absorbent dosage, initial dye concentration, temperature and pH of dye solution. The experimental results show that the amount of dye adsorbed increases with an increase in the amount of hydroxyapatite. The maximum adsorption occurred at the pH value of 5. The equilibrium uptake was increased with an increase in the initial dye concentration in solution. The experimental isotherm data were analyzed using Langmuir isotherm equation. The maximum monolayer adsorption capacity was 50.25 mg/g. The adsorption has a low temperature dependency and was endothermic in nature with an enthalpy of adsorption of 2.17 kJ mol⁻¹.     

Characteristics of granular boehmite and its ability to adsorb phosphate from aqueous solution

In this study, we investigated the surface properties of granulated boehmite with vinyl acetate (G-BE20) and measured the amount of phosphate it adsorbed and the effect of contact time and solution pH on the adsorption process. The specific surface area (144.9?m²/g) and the number of surface hydroxyl groups (0.88?mmol/g) of G-BE20 were smaller than those of virgin boehmite (BE), which gave a specific surface area and number of surface hydroxyl groups of 297.0?m²/g and 1.08?mmol/g, respectively. The amount of phosphate adsorbed increased with the temperature. The isotherm model of Langmuir was used to fit experimental adsorption equilibrium data for phosphate adsorption onto G-BE20. The calculated thermodynamic parameters show the spontaneous and endothermic nature of the adsorption process. The equilibrium adsorption onto G-BE20 was reached within 16?h and the amount of phosphate adsorbed was 8.4?mg/g. The kinetic mechanism of phosphate uptake was evaluated with two different models: the Largergren pseudo first- and pseudo second-order models. The data obtained showed a better fit to the pseudo second-order model (0.991) than to the pseudo first-order model (0.967), as indicated by the r values. The rate constants for the adsorption of phosphate onto G-BE20 were calculated as 0.481?1/h and 0.029?g/mg?h. The adsorption of phosphate onto G-BE20 was the maximum in the pH range 3.0-4.0.