鄂、湘两省山地土壤粘粒矿物的研究──Ⅳ.幕阜山土壤的粘粒矿物与表面性质

本文对幕阜山五个海拔高度计２１个土层的土样，测定了粘粒矿物组成，阳离子交换量，电荷量和对磷酸根的吸附。结果表明，随着海拔升高、粘粒的层状矿物，氧化物组成和有机质含量出现规律性变化，从而导致了粘粒的表面电荷性质和离子吸附特性出现相应差异，表现为阳离子交换量和阴离子交换量升高，土壤可变电荷量增高，对磷酸根离子的吸附量增大，解吸率降低。     

有机磷与土壤矿物相互作用及其环境效应研究进展

土壤有机磷是土壤环境中重要的磷组分,其在环境中的界面反应影响着磷素的迁移、转化、生物有效性以及环境行为。本文主要总结了土壤中典型有机磷在矿物表面的吸附-解吸、溶解-沉淀等反应特性和微观机制,以及有机磷-矿物相互作用对有机磷形态、金属离子界面反应行为,以及矿物胶体化学稳定性与溶解转化的影响等环境效应。土壤有机磷可含多个磷酸基团,相对分子质量大,电荷密度高,通过界面反应与环境矿物发生强烈的相互作用,并影响矿物的电荷性质、共存金属离子的吸附特性、以及胶体化学稳定性。有机磷界面反应特性和机制受矿物类型和结晶度、有机磷相对分子质量、pH、温度和共存离子等因素的影响。有机磷在矿物表面的吸附密度一般随着体系pH、矿物结晶度和有机磷相对分子质量的升高而降低。有机磷一般可在矿物表面形成内圈络合物,某些情况下还存在氢键作用,甚至转化形成表面沉淀。有机磷和金属离子在矿物表面的吸附一般存在协同效应(尤其是在低pH条件下),即金属离子促进了有机磷的吸附,有机磷也促进金属离子的固定;吸附机制因反应体系而异,主要包括形成三元表面络合物和表面沉淀等,多数时候存在多种机制的共同作用。最后讨论了环境中有机磷与矿物相互作用的主要研究热点和方向。     

电解质种类和浓度影响磷酸根解吸的机理研究

本文研究了吸附性阳离子、电解质浓度和组成影响几种矿物和土壤吸附态磷的解吸的机理。结果表明,吸附性阳离子影响磷酸根解吸与离子桥有关。桥接静电场愈强,被束缚磷的释放就愈困难。电解质阳离子对磷酸根解吸的影响则取决于其对表面负电荷的屏蔽效应。阳离子电价高,屏蔽作用大,磷解吸就少。电解质浓度影响吸附态磷的解吸主要与表面电位的变化有关。当pH>PZC值时,提高电解质浓度降低表面负电位,从而减少磷的吸附;当pH<PZC时,提高电解质浓度则降低表面正电位,促进磷的解吸。磷酸根解吸盐效应零点(P_PZSE)值一般都介于土壤或矿物样品吸附磷酸根前后测得的两个PZC值之间。不同浓度电解质溶液中磷解吸量之差与吸附层电位变化量(△ψ_x)呈正相关。     

铁氧化物-胡敏酸复合物对磷的吸附吸附

本试验通过设置不同磷酸根浓度、 pH和不同电解质及电解质强度梯度,研究磷酸根在针铁矿-胡敏酸（HA）复合物和赤铁矿-胡敏酸（HA）复合物表面的吸附特性。X射线衍射（XRD）、 扫描电镜（SEM）和红外光谱（FTIR）图谱显示: 铁氧化物包覆胡敏酸后其内部结构特性保持不变; 氧化铁与胡敏酸通过氢键形成粒径大、 表面光滑的铁氧化物-HA复合微粒,且复合物比表面减小; 形成的氧化铁-胡敏酸复合物对磷的吸附能力增强,且针铁矿复合物的吸附能力大于赤铁矿复合物,均为多层吸附过程; pH增高抑制铁氧化物复合物对磷的吸附,同时电解质浓度增加促进复合体对磷的吸附,且反应后体系pH随之降低。     

基于不同分析方法研究磷酸根在矿物表面吸附机制的进展

磷素是植物生长必需的营养元素,也是联系生态系统中生物与非生物作用的关键元素。对磷酸根在矿物表面吸附反应机制的深入认识,有助于了解其在陆地和水环境中的形态、迁移、转化和生物有效性。本文主要综述了磷酸根在常见(土壤)矿物表面吸附机制的研究进展。各种分析技术或方法,如OH–释放量分析、Zeta电位分析(电泳迁移率测试)、等温滴定量热法、原子力显微镜、X射线光电子能谱、红外光谱、核磁共振波谱、X射线吸收光谱、表面络合模型、量子化学计算等,均以不同方式揭示磷酸根在不同矿物体系的吸附机制。磷酸根在矿物(尤其是铁、铝氧化物)表面的吸附通常伴随着水基和羟基的交换。一般认为磷酸根在矿物表面主要形成双齿双核、单齿单核内圈络合物,且受pH的影响较大。pH以及磷酸根在矿物表面的吸附密度影响内圈络合物的质子化状态。在低pH、高磷浓度、较高反应温度、较长吸附时间,以及弱晶质矿物吸附等条件下矿物表面吸附的磷可在矿物表面转化形成含磷的表面沉淀,造成矿物溶解转化以及磷生物有效性的进一步降低。最后展望了磷酸盐在矿物-水界面吸附有关的研究热点和方向。     

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。     

有机阴离子对磷酸根吸附的影响

在中性条件下,低浓度的柠檬酸、草酸、酒石酸和胡敏酸阴离子都能显著降低针铁矿、非晶氧化铝、高岭石和红壤对磷酸根的吸附,尤其在低磷吸附饱和度下效果更好。有机阴离子抑制磷酸根吸附的能力因有机酸的种类和性质、以及固相的表面特性而异。有机阴离子存在下吸附的磷酸根具有较高的同位素³²P交换活性和解吸率。测定了吸附平衡溶液中铁和铝的浓度。结果表明,在实验条件下(pH 7.0),即使较高浓度的有机酸根(10^-2mol)也只能溶解极少量的铁和铝。有机阴离子络溶作用不足以说明固相吸附磷能力的显著下降。可见,有机阴离子降低磷酸根吸附的机制主要是竞争专性吸附。有机阴离子占据了一部分高亲和力的吸附位,从而降低了土壤固相吸附磷的量,增加了吸附态磷的活性。     

土壤镉吸附的研究进展

综述了土壤镉吸附的机理和土壤pH、有机质含量、粘粒矿物类型及含量、土壤溶液中竞争性阳离子、共存阴离子、土壤温度等土壤性质对土壤镉吸附的影响；总结了土壤镉的吸附量随土壤pH增加、温度升高及有机质、铁锰氧化物和粘土矿物含量增加而增加的机理；竞争性阳离子的存在抑制镉的吸附，土壤溶液中共存阴离子对镉吸附的影响取决于阴离子种类和土壤类型。     

pH和三种阴离子对紫色土亚硒酸盐吸附-解吸的影响

p H和三种竞争性阴离子对紫色土亚硒酸盐吸附-解吸的影响的研究结果表明,随着p H的增大,紫色土对亚硒酸盐的吸附量减少,酸性条件下紫色土对亚硒酸盐吸附量最大。平衡液中加入磷酸氢二钠显著降低了土壤对亚硒酸盐的吸附,硫酸盐对紫色土吸附亚硒酸盐的影响很小,低浓度碳酸氢根离子对紫色土吸附亚硒酸盐具有促进作用,但高浓度的碳酸氢根离子则降低了紫色土吸附亚硒酸盐。磷酸氢根离子和硫酸根离子对亚硒酸盐吸附的影响符合Langmuir和Freundlich拟合方程式,决定系数R2值均在0.90以上。三种阴离子对亚硒酸盐的解吸影响不同,当有磷酸氢根离子和碳酸氢根离子存在时,亚硒酸盐的解吸率增大,而硫酸根离子的存在却对紫色土亚硒酸盐的解吸影响不大。在紫色土地区农业生产中采用含磷酸盐肥料和碱性碳酸氢铵肥料,这些措施可能增加土壤硒的有效性,进而增加植物硒吸收和积累。认识紫色土固液界面硒的吸附-解吸规律,可为提高紫色土地区硒生物有效性,从而进一步提高农产品中硒含量提供科学依据。     

胡敏酸吸附解吸Fe3+反应特征研究

采用C-25葡聚糖凝胶层析方法研究了在不同酸度、离子强度、温度条件下胡敏酸（HA）吸附解吸Fe3^＋特征.结果表明,在相同离子强度、反应温度条件下,随着pH的升高,HA对Fe（Ⅲ）最大吸附量Smax和吸附平衡常数k增加,标准摩尔自由能变△Gom绝对值减小.相同pH和温度下,离子强度从0.00到0.10mol L^-1,HA对Fe（Ⅲ）最大吸附量Smax和吸附亲和力常数k增加,自由能变△G^o m绝对值减小,但离子强度从0.10 mol L^-1继续上升到0.15 mol L^-1,则上述特征常数变化刚好相反.温度升高,胡敏酸吸附Fe3^＋的最大吸附量、吸附平衡常数k、自由能变△G^o m绝对值均较大幅度降低,表明升高温度对吸附反应不利.吸附反应的焓变△H^o m和熵变△S^o m均小于零,为放热反应,反应向更有序状态进行;在相同条件下,pH越大,焓变△H^o m和熵变△rS^θ m绝对值越大,表明pH越大,越有利于吸附反应的进行.随着pH的升高,Fe3^＋被还原的百分率η减小,用幂函数方程拟合,相关系数达到显著水平.随着pH的降低,胡敏酸铁Fe3^＋解吸率增大;对解吸率曲线进行拟合,线形方程具有显著的相关系数.胡敏酸吸附Fe3^＋的反应为包括胡敏酸内部和外部结合的“两相”反应.     

磷酸盐在水铁矿及水铁矿-胡敏酸复合体表面的吸附

The adsorption of phosphate onto ferrihydrite (FH) and two FH-humic acid (HA) complexes, obtained by co-precipitating FH with low (FH-HA1) and relatively high amounts of humic acid (FH-HA2), was studied through kinetics and isotherm experiments to determine the differences in phosphate adsorption between FH-HA complexes and FH and to reveal the mechanism of phosphate adsorption onto two soil compositions. The isoelectric point (IEP) and the specific surface area (SSA) of the mineral decreased as the particle porosity of the mineral increased, which corresponded to an increase in the amount of organic carbon. The adsorption capacity of phosphate was higher on FH than on FH-HA1 and FH-HA2 at the scale of micromoles per kilogram. The initial adsorption rate and adsorption affinity of phosphate decreased with an increase in the amount of HA in the mineral. The sensitivity of phosphate adsorption to the change in the pH was greater for FH than for FH-HA complexes. Ionic strength did not affect the adsorption of phosphate onto FH and FH-HA1 at a lower pH, and the increase in the ionic strength promoted phosphate adsorption at a higher pH. However, for the FH-HA2 complex, the increase in the ionic strength inhibited the adsorption of phosphate onto FH-HA2 at a lower pH and increased the adsorption at a higher pH.     

Interactive Sorption of Metal Ions and Humic Acids onto Mineral Particles

The sorption of metal ions (Pb2+, Zn2+ and Cu2+) and soil humic acids (HA) from aqueous solutions onto mineral particles (sand, calcite and clay) was investigated using a batch equilibrium system. The sorption reactions in two- component systems (heavy metals-mineral particles and humic acids- mineral particles), as well as interactions in three-component system (heavy metals-humic acids-mineral particles) were examined. Results showed that the presence of humic acids, dissolved or bound onto mineral surfaces, considerably influenced the fixation of heavy metals. The various effects, depending on mineral type, humic concentration and specific metal-ion, were observed in three- component system. Sorption of Cu2+-ions on all minerals studied rapidly increased as the concentration of dissolved HA increased. The amount of Pb2+-ions sorbed on sand slightly decreased, while on kaolin increased between 15 and 20%. Sorption of Zn2+-ions on all minerals studied decreased at pH 4. At pH 5.5 the sorption of Zn2+-ions onto calcite decreased, while on kaolin and sand increased as a function of the humic acid concentration giving the curve with maximum at c(HA) = 2.5 mmol C L-1. At pH 6.5 sorption onto kaolin and sand increased. This effect occurs as a result of the conditional stability constant of Zn-HA complexes increasing at higher pH which in turn promotes the chelation of Zn2+-ions to mineral- bound humic substances. The enhanced sorption of metal ions from the aqueous phase in three-component systems is not only the result of mineral sorption of free metals but also the result of chelation with HA sorbed on the mineral surface.     

Interactions of organic phosphorus with soil minerals and the associated environmental impacts: A review

As an important part of the soil phosphorus(P) pool, organic P(OP) is widely found in terrestrial and aquatic environments(e.g., soils and sediments).The interfacial behavior of OP on natural minerals affects the transport, transformation, and bioavailability of P in the environment. This paper reviews the processes involving adsorption-desorption, dissolution-precipitation, and enzymatic/mineral-mediated hydrolysis of OP at the mineral-water interface, and their subsequent effects on OP speciat...     

Sorption of cadmium by complexes of kaolinite with humic acid

Abstract

Levels of cadmium (Cd) in New Zealand pastoral soils have increased due to Cd impurities in applied fertilisers. As there is little information on the interaction of Cd with soil mineral‐organic matter complexes, the sorption of Cd by complexes of kaolinite with humic acid has been investigated. Sorption was measured at pH and ionic strength values typically found for solutions of pastoral soils in New Zealand. Sorption increased with the content of humic acid in the complex, and as the pH of the medium was raised from 4.2 to 6.3. Sorption was also influenced by the ionic strength of the ambient solution, notably by the nature of the cation in the added electrolyte. The experimental data were interpreted in terms of the effect of solution pH and ionic composition on the charge characteristics of kaolinite and humic acid. These factors, in turn, influence clay particle association as well as the clay‐humic and metal‐humic interaction.     

Effects of pH,solid/solution ratio,ionic strength,and organic acids on Pb and Cd sorption on kaolinite

Potentiometric and ion-selective electrode titrations together with batch sorption/desorption experiments, were performed to explain the aqueous and surface complexation reactions between kaolinite, Pb, Cd and three organic acids. Variables included pH, ionic strength, metal concentration, kaolinite concentration and time. The organic acids used were p-hydroxybenzoic acid, o-toluic acid, and 2,4-dinitrophenol. Titrations were used to derive previously unavailable aqueous conditional stability constants for the organometallic complexes. Batch results showed that aqueous lead-organic complexation reduced sorption of Pb by kaolinite. Cadmium behavior was similar, except for 2,4-dinitrophenol, where Cd sorption was increased. Metal sorption increased with increasing pH and decreasing ionic strength. Distribution ratios (K _d 's) decreased with increasing solid/solution ratio. The subsurface transport of lead and cadmium may be enhanced via complex interactions with organic wastes or their degradation products and sorbent mineral surfaces.

     

A mechanistic model for describing the sorption and desorption of phosphate by soil

A model of phosphate reaction is constructed and its output compared with observations for the sorption and desorption of phosphate by soil. The model has three components: first, the reaction between divalent phosphate ions and a variable-charge surface; second, the assumption that there is a range of values of surface properties and that these are normally distributed; third, the assumption that the initial adsorption induces a diffusion gradient towards the interior of the particle which begins a solid-state diffusion process. The model closely describes the effects on sorption of phosphate of: concentration of phosphate, pH, temperature, and time of contact. It also reproduces the effects on desorption of phosphate of: period of prior contact, period and temperature of desorption, and soil: solution ratio. The model is general and should apply to other specifically adsorbed anions and cations. It suggests that phosphate that has reacted with soil for a long period is not ‘fixed’ but has mostly penetrated into the soil particles. The phosphorus can be recovered slowly if a low enough surface activity is induced.     

Selenite adsorption by a variety of oxides

Abstract

Selenite adsorption by a variety of oxides consisting of iron (Fe), aluminum (Al), titanium (Ti), manganes (Mn), and silicon (Si), and by two humic acids were investigated in order to grasp selenite behavior and fixation mechanisms in soil. It was found that selenite was apparently adsorbed even by the Mn oxides on which surface negative charge was dominant in normal pH range (pH <4). No selenite adsorption was observed in the silicon dioxide (SiO₂) and the two humic acids. A sequential extraction of adsorbed selenite with competitive anions showed the differences of binding force or stability of adsorbed selenite among the minerals. While the goethite fixed selenite strongly, selenite adsorbed on the Mn oxide was easily released to the liquid phase with other anions, such as phosphate. Each mineral had its inherent characteristic in ligand exchange reactions accompanied with selenite sorption. Selenite sorption by the Mn and the Ti oxides resulted in large increase of surface negative charge, while only a little increase in the Fe and Al oxides. Proton consumption with selenite sorption was extremely smaller for the Mn oxide than for the others.