温度对硼在三种矿物上吸附-解吸特性的影响

在实验室对天然Ca 蒙脱进行了纯化 ,并在一定条件下人工合成了针铁矿、水锰矿 ,以此作为实验材料 ,用吸附—解吸平衡法和反应动力学方法研究了温度对硼在Ca 蒙脱 ,针铁矿 ,水锰矿上的吸附、解吸特性的影响。结果表明 :随温度升高 ,Ca 蒙脱对硼的吸附量升高 ,其对硼的解吸滞后性下降 ,水锰矿和针铁矿对硼的吸附量下降 ,其对硼的解吸滞后性加强。计算表明 ,在常温下 ,硼在Ca 蒙脱上的吸附热为 63.0 8kJmol- 1 ,在针铁矿和水锰矿上分别为 - 1 2 2 .45和 - 93 .91kJmol- 1 ,硼在Ca 蒙脱、针铁矿和水锰矿上的解吸热分别为- 31 .0 2 ,53 .95和 46 .30kJmol- 1 。上述结果说明 ,硼在Ca 蒙脱上的吸附为吸热过程 ,解吸为放热过程 ;硼在针铁矿、水锰矿上的吸附为放热过程 ,解吸为吸热过程。随着温度的升高 ,硼与矿物的初始反应速率明显加快 ,而整体反应速率略有下降。     

铁铝氧化物–层状硅酸盐矿物互作对Cr (Ⅵ)和As (Ⅴ)吸附的影响

以高岭石、蒙脱土、针铁矿和三水铝石四种单一典型土壤矿物以及针铁矿-蒙脱石和三水铝石-蒙脱石（质量比为1:1）两种代表性土壤矿物复合体为吸附材料，采用吸附平衡实验、能谱分析（(EDS）、红外光谱、扫描电镜、酸碱滴定和zeta电位测定等方法，研究了铁铝氧化物与层状硅酸盐矿物之间的相互作用对Cr(Ⅵ)和As(Ⅴ)吸附的影响及其机制。吸附平衡实验和EDS实验结果表明，两种复合体对Cr(Ⅵ)和As(Ⅴ)的吸附容量均小于其两种组成矿物单一体系吸附量的平均值，即铁铝氧化物与蒙脱石的互作降低了这些氧化物对Cr(Ⅵ)和As(Ⅴ)的吸附能力。表面性质表征结果表明，与蒙脱石复合后，针铁矿与三水铝石表面的正电荷均被完全中和，电荷符号发生反转。与理论值相比，三水铝石-蒙脱石复合体的表面位点总浓度无明显变化，比表面积减小。针铁矿-蒙脱石复合体的比表面积与理论值无明显差异，但矿物表面位点浓度减小，表面羟基红外吸收峰强度减弱。氧化物与层状硅酸盐矿物互作改变了矿物表面性质，这可能是导致氧化物对Cr(Ⅵ)和As(Ⅴ)的吸附能力降低的主要原因。当评估污染元素在土壤中有效性时应当考虑土壤固相组分间的互作对离子吸附的影响。     

不同pH条件下添加纳米型蒙脱土和高岭土对溶液中铜的去除效果研究

通过有机插层法对蒙脱土、高岭土进行改性,制备成纳米型蒙脱土、高岭土,并利用制备的纳米型高岭土、蒙脱土对溶液中铜的吸附效果及吸附机理进行了研究。结果表明,纳米型蒙脱土和高岭土对溶液中的铜具有很好的去除效果,其吸附等温线可以用Langmuir和Freundlich方程进行拟合。相比而言,蒙脱土比高岭土具有较高的吸附量和吸附亲和力参数。在溶液中铜离子浓度低于120 mg/L时,纳米型蒙脱土、高岭土对铜的最大去除率分别达到99.5%和94.3%,对溶液中铜的去除率随铜离子浓度增加和溶液的pH降低而降低。     

离子强度对可变电荷表面吸附性铜离子解吸的影响:高岭石

为了解连续性解吸对可变电荷表面吸附性铜离子解吸的影响,研究了高岭石在去离子水和0.1 mol L~(-1) NaNO_3溶液中吸附铜离子后,依次在去离子水以及浓度由低到高的NaNO_3溶液中连续解吸时,离子强度变化对不同pH段铜离子解吸的影响。结果表明:在去离子水中和不同浓度NaNO_3中解吸吸附性铜离子时,pH-解吸分值曲线的变化趋势完全不同。在去离子水中解吸时可出现重吸附现象,而在NaNO_3中解吸时出现解吸峰现象。高岭石pH-铜离子解吸分值曲线的拐点pH与pH吸附有着对应关系,且pH特征与高岭石pH0关系密切。离子强度变化导致的吸附表面电位变化、高岭石边面的诱导水解作用和土壤表面电荷性质随pH升高的变化被认为是导致这些现象的原因。     

连续解吸中离子强度对可变电荷表面吸附性铜离子解吸的影响 ：高岭石

为了解连续性解吸对可变电荷表面吸附性铜离子解吸的影响,研究了高岭石在去离子水和0.1 mol L~(-1) NaNO_3溶液中吸附铜离子后,依次在去离子水以及浓度由低到高的NaNO_3溶液中连续解吸时,离子强度变化对不同pH段铜离子解吸的影响。结果表明:在去离子水中和不同浓度NaNO_3中解吸吸附性铜离子时,pH-解吸分值曲线的变化趋势完全不同。在去离子水中解吸时可出现重吸附现象,而在NaNO_3中解吸时出现解吸峰现象。高岭石pH-铜离子解吸分值曲线的拐点pH与pH吸附有着对应关系,且pH特征与高岭石pH0关系密切。离子强度变化导致的吸附表面电位变化、高岭石边面的诱导水解作用和土壤表面电荷性质随pH升高的变化被认为是导致这些现象的原因。     

Sb(Ⅲ)和Sb(Ⅴ)在不同吸附剂上的吸附特征

以氢氧化铁、氢氧化铝、高岭土和蛭石4种材料为吸附剂,探究Sb(Ⅲ)和Sb(Ⅴ)的吸附效果,以类比土壤中主要矿物对Sb的吸附作用并进行对比。研究内容包括吸附动力学试验、等温吸附试验及不同背景溶液pH变化下的吸附解吸效应。结果表明:4种吸附剂对Sb(Ⅲ)和Sb(Ⅴ)的吸附在振荡24 h后逐渐趋于平稳,蛭石和氢氧化铁对Sb(Ⅲ)的吸附量在6 h达到峰值后出现下降,如氢氧化铁在6 h时对Sb(Ⅲ)的吸附量为23.19μg/g,72 h后降为19.75μg/g,并测定出该悬浮液中Sb(Ⅴ)浓度上升。用Langmuir和Freundlich吸附模型对两种价态Sb的等温吸附曲线进行拟合,两种模型拟合优度均在0.7以上。蛭石和氢氧化铁对Sb(Ⅲ)的吸附效果好于另两种吸附剂,而蛭石对Sb(Ⅴ)的吸附能力较弱;氢氧化铁和氢氧化铝对Sb(Ⅴ)的吸附效果较好,而氢氧化铝对Sb(Ⅲ)吸附效果不理想。随着pH的增加,Sb(Ⅲ)和Sb(Ⅴ)的吸附出现明显下降,并且解吸率增加,表现出pH对吸附的显著影响,如高岭土对Sb(Ⅲ)的吸附量由平衡液pH为4.82时的10.12μg/g增加到pH为2.12时的37.89μg/g。     

水铁矿对磷的吸附及胶体态磷迁移能力预测

土壤中流失的磷进入水体容易引起富营养化污染。目前对于铁矿物胶体结合态磷在土壤孔隙介质中的稳定性和迁移能力的认识还存在不足。本研究采用吸附试验,考察水铁矿对磷的吸附特征以及pH、离子强度和胡敏酸对磷在液相、水铁矿胶体和水铁矿固体上分布的影响;通过DLVO理论,预测水铁矿胶体结合态磷的稳定性和迁移能力。结果表明,假二级动力学模型(R~2=0.964)更适合用于描述磷在水铁矿上的吸附过程,磷在水铁矿上的吸附受液膜扩散、内部扩散和化学吸附等过程控制。Freundlich模型(R2=0.970)对等温吸附的拟合效果好,说明水铁矿对磷的吸附为多层吸附过程。从Langmuir模型参数可知,水铁矿对磷的最大理论吸附量为22.55mg·g~(-1)。水铁矿对磷的吸附能力随pH的升高而降低,随离子强度的升高而升高。然而,低离子强度和高pH有利于反应体系中水铁矿胶体的释放。无论胡敏酸是否存在,在碱性且离子强度不高(1～10mmol·L~(-1))的条件下,有约5%～20%的磷会与水铁矿胶体结合,且这些磷-水铁矿胶体之间的静电斥力较大。根据DLVO理论计算可知,这些带负电荷的胶体之间稳定性较好,在土壤中有一定迁移能力。在实际农业活动中,磷肥的过量施用可能会使大量的磷酸根离子吸附在铁矿物上,促进土壤孔隙水中形成稳定的、带负电的铁矿物胶体,这种磷-铁矿物复合胶体的迁移很可能成为磷迁移的另一种形式。本研究结果可为胶体促进下磷淋失风险评估提供理论和数据支撑。     

离子强度和磷酸盐对铁铝矿物及土壤吸附As（V）的影响

选用针铁矿、赤铁矿、水铁矿、水铝矿4种铁铝矿物以及性质差异较大的黑土、紫色土和红壤3种土壤,研究离子强度和磷酸盐对其吸附As（V）的影响。结果表明,在0．01、0．1、1mol·L^-13种离子强度下,矿物和土壤对As（V）的吸附量无明显差异或随离子强度增大而增大,其对砷的吸附以专性吸附为主。磷酸盐对矿物和土壤吸附砷的影响与其添加顺序及摩尔浓度比有关。水铝矿和水铁矿在这3种添加顺序下的砷吸附量无明显差异,仅在P／As摩尔比较大时表现出下降趋势;而在针铁矿和赤铁矿两种矿物上,先添加砷时的砷吸附量高于先添加磷时或两者同时添加时,且砷吸附量随WAs摩尔比的增加而逐渐下降。在黑土、紫色土和红壤上,先添加砷比先添加磷或两者同时添加时的砷吸附量均要高,尤其是在紫色土上。随P／As摩尔比升高,土壤对砷的吸附量表现出下降趋势。     

支持电解质浓度对磷酸根在可变电荷土壤表面吸附和解吸的影响

研究了离子强度对2种可变电荷土壤中磷酸根吸附和解吸的影响。结果表明,当pH分别大于3.7和4.0时,红壤和砖红壤对磷酸根的吸附量随离子强度的增加而增加;当pH分别小于3.7和4.0时,红壤和砖红壤对磷酸根的吸附量随离子强度呈相反的变化趋势。电解质主要通过改变离子专性吸附面上的电位来影响磷酸根的吸附。Zeta电位的测定结果表明,当pH大于土壤胶体的等电点(IEP)时,吸附面上电位为负值,且随离子强度增加数值减小,对磷酸根的排斥力减小,土壤表面对磷酸根的吸附量增加;当pH小于IEP时,吸附面上的电位为正值,它随离子强度增加而减小,不利于磷酸根的吸附。解吸实验的结果表明,吸附于可变电荷土壤表面的磷酸根在去离子水中的解吸量高于0.1 mol L-1NaNO3体系中的解吸量。这同样由于电解质浓度对土壤表面吸附面上的电位的影响所致。     

磷酸根在矿物表面的吸附-解吸特性研究进展

综述了磷酸根在一些常见土壤矿物表面吸附–解吸特性的研究进展。磷酸根在矿物表面的吸附特性受环境pH、离子强度、温度、反应时间、矿物类型等多种因素的共同影响。一般说来,矿物表面的磷吸附量随pH降低而增加,受离子强度的影响较小。磷酸根在矿物表面的吸附动力学过程可分为快速吸附过程和慢速吸附过程,且在弱结晶矿物中存在微孔扩散过程。磷酸根在矿物表面的解吸过程通常存在两个阶段(初始快速解吸和随后的缓慢解吸),在解吸反应后期甚至还会发生再吸附。此外,磷酸根的吸附特性也受共存阴离子配体或金属阳离子的影响。其中,共存阴离子通过位点竞争、静电作用和空间位阻效应等机制影响磷酸根的吸附。天然有机质(包括胡敏酸和富里酸)降低了磷酸根在矿物表面的吸附,特别是在低p H条件下。通常,富里酸比胡敏酸更能有效降低磷酸根在矿物表面的吸附。金属阳离子可通过表面静电效应、形成三元络合物以及形成表面沉淀等机制促进磷酸根和金属在矿物表面的共吸附。最后,展望了与磷酸根在矿物表面吸附特性有关的研究热点和方向。     

铁铝氧化物和高岭石对转化酶的吸附及活性的影响

Experiments were conducted to study the influences of synthetic bayerite, non-crystalline aluminum oxide (N-AlOH), goethite, non-crystalline iron oxide (N-FeOH) and kaolinite on the adsorption, activity, kinetics and thermal stability of invertase. Adsorption of invertase on iron, aluminum oxides fitted Langmuir equation. The amount of invertase held on the minerals followed the sequence kaolinite > goethite > N-AlOH > bayerite > N-FeOH. No correlation was found between enzyme adsorption and the specific surface area of minerals examined. The differences in the surface structure of minerals and the arrangement of enzymatic molecules on mineral surfaces led to the different capacities of minerals for enzyme adsorption. The adsorption of invertase on bayerite, N-AlOH, goethite, N-FeOH and kaolinite was differently affected by pH. The order for the activity of invertase adsorbed on minerals was N-FeOH > N-AlOH > bayerite > reak goethite > kaolinite. The inhibition effect of minerals on enzyme activity was kaolinite > crystalline oxides > non-crystalline oxides. The pH optimum of iron oxide- and aluminum oxide-invertase complexes was similar to that of free enzyme (pH 4.0), whereas the pH optimum of kaolinite-invertase complex was one pH unit higher than that of free enzyme. The affinity to substrate and the maximum reaction velocity as well as the thermal stability of combined invertase were lower than those of the free enzyme.     

Adsorption of DNA on clay minerals and various colloidal particles from an Alfisol

Adsorption and desorption of salmon sperm DNA on four different colloidal fractions from Brown Soil and clay minerals were studied. The adsorption isotherms of DNA on the examined soil colloids and minerals conformed to the Langmuir equation. The amount of DNA adsorbed followed the order: montmorillonite?fine inorganic clay>fine organic clay>kaolinite>coarse inorganic clay>coarse organic clay. A marked decrease in the adsorption of DNA on organic clays and montmorillonite was observed with the increase of pH from 2.0 to 5.0. Negligible DNA was adsorbed by organic clays above pH 5.0. As for inorganic clays and kaolinite, a slow decrease in DNA adsorption was found with increasing pH from 2.0 to 9.0. The results implied that electrostatic interactions played a more important role in DNA adsorption on organic clays and montmorillonite. Magnesium ion was more efficient than sodium ion in promoting DNA adsorption on soil colloids and minerals. DNA molecules on soil colloids and minerals were desorbed by sequential washing with 10 mM Tris, 100 mM NaCl and 100 mM phosphate at pH 7.0. A percentage of 53.7-64.4% of adsorbed DNA on organic clays and montmorillonite was released, while only 10.7-15.2% of DNA on inorganic clays and kaolinite was desorbed by Tris and NaCl. The percent desorption of DNA from inorganic clays, organic clays, montmorillonite and kaolinite by phosphate was 39.7-42.2, 23.6-28.8, 29.7 and 11.4%, respectively. Data from this work indicated that fine clays dominate the amount of DNA adsorption and coarse clays play a more important role in the binding affinity of DNA in soil. Organic matter may not favor DNA adsorption in permanent-charge soil. The information obtained is of fundamental significance for the understanding of the ultimate fate of extracellular DNA in soil.     

Hydrolysis of cellobiose by β-glucosidase in the presence of soil minerals - Interactions at solid-liquid interfaces and effects on enzyme activity levels

Extracellular enzymatic activities in soils are essential for the cycling of organic matter. These activities take place in multiphase environments where solid phases profoundly affect biocatalytic activities. Aspergillus niger is ubiquitous in soils; its β-glucosidase plays an important role in the degradation of cellulose, and therefore in the global carbon cycle and in the turnover of soil organic matter. However, the information on the interactions of this protein with soil minerals is very limited, and even less is known about their consequences for the hydrolysis of the natural substrate cellobiose. We therefore characterised the sorptive interactions of this enzyme with the soil minerals montmorillonite, kaolinite and goethite and quantified the resulting changes in the hydrolysis rate of cellobiose. Fractions of adsorbed protein, and the resulting catalytic activity loss, were lower for montmorillonite than for kaolinite and goethite at given experimental conditions; adsorption was 9.7 ± 7.3% for montmorillonite, 70.3 ± 3.1% for kaolinite and 71.4 ± 1.8% for goethite, respectively. Adsorption of the protein to the minerals caused a total decrease in the catalytic activity of 18.8 ± 3.4% for kaolinite and 17.9 ± 4.7% for goethite whereas it was not significant for montmorillonite. The average catalytic activity lost by the pool of adsorbed molecules was 26.8% for kaolinite and 25.0% for goethite. Both the amount of adsorbed protein and the resulting loss of catalytic activity were found to be independent of the specific surface areas yet were influenced by the electrical properties of the mineral surfaces. Under the experimental conditions, montmorillonite and kaolinite are negatively charged whereas goethite is positively charged. However, because of the adsorption of phosphate anions from the buffer, a charge reversal took place at the surface of goethite. This was confirmed by zeta (ζ)-potential measurements in phosphate buffer, revealing negative values for all the tested minerals. Indeed goethite interacted with the enzyme as a negatively charged surface: the amount of adsorbed protein and the resulting catalytic activity loss were very similar to those of kaolinite. Our results show that, even if an important fraction of β-glucosidase is adsorbed to the minerals, the catalytic activity is largely retained. We suggest that this strong activity retention in presence of soil minerals results from a selective pressure on A. niger, which benefits from the activity of the adsorbed, and thus stabilized, enzyme pool.     

低分子量有机配体对黏粒矿物吸附苏云金芽孢杆菌的影响

土壤是微生物的理想栖息地,土壤微生物群落组成复杂,数量巨大。1g土壤中可能栖息着上百亿个微生物,其中细菌可达1010个[1]。约80%～90%的土壤微生物寄居于土壤固相表面,如黏土矿物、金属氧化物或有机质表面[2]。细菌与矿物间的相互作用在土壤污染物转化与降解、团聚体形成[3]、矿物风化[4-6]及病原菌运移[7-8]等诸多过程起着关键作用。     

Effects of Addition Sequence and pH of Oxalate on the Adsorption and Activity of Acid Phosphatase on Soil Colloids and Minerals

The adsorption and specific activities of acid phosphatase on soil colloids and minerals in oxalate systems with different pH values were studied using the batch method. Results indicated that the amount of phosphatase adsorption decreased in the following order: goethite ? yellow-brown soil (YBS) > kaolinite > latosol, and the specific activities of immobilized phosphatase were goethite > latosol > kaolinite > YBS. The profiles of enzymatic adsorption and specific activity on soil minerals were bell shaped, and their change tendencies were out of sync. The optimal pH for phosphatase adsorption was located between the isoelectric point of phosphatase and the zero point of charge of the studied soil minerals, and the optimal pH for the specific activity of the immobilized enzyme either did not change or shifted toward alkalinity. Enzymatic adsorption amounts and specific activities were greater when the enzyme was added before oxalate than when enzyme was added after oxalate.     

有机酸对高岭石, 针铁矿和水铝英石吸附镉的影响

Effects of organic acids （oxalic, acetic, and citric） on adsorption characteristics of Cadmium （Cd） on soil clay minerals （kaolinite, goethite, and bayerite） were studied under different concentrations and different pH values. Although the types of organic acids and minerals were different, the effects of the organic acids on the adsorption of Cd on the minerals were similar, i.e., the amount of adsorbed Cd with an initial solution pH of 5.0 and initial Cd concentration of 35 mg L^-1 increased with increasing concentration of the organic acid in solution at lower concentrations, and decreased at higher concentrations. The percentage of Cd adsorbed on the minerals in the presence of the organic acids increased considerably with increasing pH of the solution. Meanwhile, different Cd adsorption in the presence of the organic acids, due to different properties on both organic acids and clay minerals, on kaolinite, goethite, or bayerite for different pHs or organic acid concentrations was found.     

Adsorption Kinetics of Pb2+ and Cu2+ on Variable Charge Soils and Minerals: Ⅲ. Adsorption Kinetics of Pb2+ Within 30 Minutes

The adsorption kinetics of Pb2+ on different soils and minerals with variable charges was studied by the two ion-selective electrode technique at different pH and concentrations. The results showed that more than 95% of adsorption on all the samples occurred during the first 5 minutes. All adsorption time-dependent data could fit the surface second-order equation very well. The values of Xm were goethite > kaolinite, and latosol > red soil at the same initial reaction concentration. The values of k were kaolinite > > goethite, and latosol > red soil at the same reaction pH and initial concentration.     

纳米粘土矿物对阿特拉津的吸附-解吸特性研究

采用批量平衡实验,研究了纳米粘土矿物与原粘土矿物对除草剂阿特拉津的吸附解吸特陛。结果表明,粘土矿物对阿特拉津的吸附-解吸均能用Freundlich方程很好地拟合。随着溶液中阿特拉津浓度的增加,粘土矿物对阿特拉津的吸附量增加;粘土矿物粒径越小,吸附量越大,纳米粘土矿物的吸附量显著大于原粘土矿物。粘土矿物对阿特拉津吸附量大小顺序为：纳米SiO2）纳米蒙脱石〉凹凸棒石〉蒙脱石〉SiO2。粘土矿物对阿特拉津的解吸表现出一定的滞后效应,即粘土矿物吸附的阿特拉津越多,解吸的越少。粘土矿物对阿特拉津的解吸率大小顺序为：SiO2〉凹凸棒石〉纳米蒙脱石〉纳米SiO2〉蒙脱石。