湿地水环境中表层沉积物吸附铅、镉能力的研究

在选定的实验条件下,对向海自然保护区5个不同类型湿地水体的表层沉积物样品进行了铅、镉的热力学吸附实验.结果表明,沉积物样品吸附铅、镉的过程符合Langmuir和Freundlich(n=8,p= 0.01) 等温吸附曲线.在所讨论的范围内,沉积物样品吸附铅、镉的能力与样品中铁、锰氧化物及有机质含量存在着显著的相关性.表层沉积物吸附铅、镉的能力小于生物膜吸附铅、镉的能力,即在湿地水环境中,生物膜对重金属迁移转化的作用相对于表层沉积物而言更重要.     

鄂尔多斯盆地延长组页岩吸附热力学特征

为了研究陆相页岩的吸附机理,以鄂尔多斯盆地甘泉地区延长组页岩为研究对象,开展了不同温度下页岩等温吸附实验,分析了延长组页岩的吸附特性及等量吸附热特征,实现了页岩等温吸附量的预测。结果表明:超临界条件下,页岩等温吸附曲线极大值的出现与实验压力、比表面积及吸附气有关;与龙马溪组页岩相比,延长组页岩等量吸附热与吸附量呈正相关关系,符合幂函数拟合,且在相同吸附量下,延长组页岩等量吸附热较低,具有较强的非均质性和较弱的吸附作用力;等量吸附热不能反映吸附性能的强弱;基于等量吸附热的页岩等温吸附曲线预测方法在低实验温度、低气体压力条件下具有较高的预测精度。      

冲积和湖积成因土壤Cd的吸附特征:以安徽省当涂县为例

为揭示冲积与湖积成因土壤镉的吸附特征,以安徽省当涂县冲积成因的江心洲和冲积、湖积成因的大陇乡根际土壤为研究对象,开展土壤镉的等温吸附实验和吸附动力学实验.等温吸附实验结果表明,冲积土壤镉的吸附量（S）、等温吸附常数（K）和固液分配系数（K_d）均较湖积土壤明显偏大,显示冲积土壤对镉的吸附能力较湖积土壤强;吸附动力学实验表明,冲积土壤的最大吸附量、平衡吸附量均较湖积土壤大,吸附速率也明显偏大,尤其在吸附实验早期更为显著;等温吸附常数K和平衡吸附速率V_b与土壤理化性质的分析表明,土壤pH是造成研究区土壤镉吸附能力差异的主要原因,其次为物理性粘粒含量;土壤pH是影响研究区冲积土壤镉吸附能力的主要因素;湖积土壤镉的吸附能力受土壤pH、有机质含量、Cd含量、物理性粘粒含量等因素的综合影响.研究对于揭示Cd在水土系统的迁移转化规律以及土壤Cd的污染防治具有重要的指导意义.      

基于Ono-Kondo格子模型的页岩气超临界吸附机理探讨

页岩气吸附机理的研究对于页岩气成藏和储量评价具有重要意义.甲烷在地层温度和压力条件下处于超临界状态,页岩气的吸附实际上为超临界吸附,但其机理目前尚不明确.在建立Ono-Kondo格子模型的基础上,结合低温氮气吸附和高压甲烷等温吸附实验,对龙马溪组页岩的微观孔隙结构和超临界吸附曲线进行了分析.结果表明,页岩中发育的孔隙尺度较小,比表面积较大,吸附气主要赋存于微孔和中孔中;页岩的等温吸附曲线在压力较大时,必然存在下降的趋势,这并非异常现象,而是超临界甲烷过剩吸附量的本质特征.Ono-Kondo格子模型对页岩高压等温吸附曲线的拟合效果很好,相关系数均在0.99以上,说明该模型可以表征页岩纳米孔隙中超临界甲烷的吸附特征.基于拟合得到的吸附相密度可将过剩吸附量转换为绝对吸附量,并直接计算地层温度和压力下甲烷的吸附分子层数,计算层数均小于1,表明甲烷分子并没有铺满整个孔隙壁面.因此受流体性质、吸附剂吸附能力和孔隙结构3个方面的影响,页岩气的吸附机理为单层吸附,不可能为双层甚至多层吸附.      

我国煤储层等温吸附常数分布规律及其意义

对我国煤储层的等温吸附资料进行了全面系统分析和总结,得出了干燥煤样等温吸附曲线校正为储层温度和平衡水条件的回归经验公式。在此基础上,探讨了我国各时代、各煤类等温吸附常数a、b值的地域和层域分布规律及其对煤层气地面开发的影响。      

不同煤级煤对H2S气体的吸附差异及吸附模型

为了研究不同煤级煤对H₂S气体的吸附差异及吸附模型,采集新疆气煤,山西潞安瘦煤、晋城无烟煤3个煤样进行了工业分析、煤岩分析和平衡水条件下的等温吸附实验。采用Langmuir,BET,D-R和D-A吸附模型,利用拟合软件对等温吸附实验数据进行了非线性回归拟合,并检验拟合程度。结果表明:煤对H₂S的吸附量随着煤化程度的加深而增加,为第Ⅰ类等温吸附线;其中Langmuir模型的拟合效果最好,n=1的D-A模型的拟合效果次之,BET模型的拟合效果较差,模型对实验数据的拟合效果与吸附模型中参数个数无明显关系;煤吸附H₂S可用单分子层吸附理论来解释。      

汞和镉在土壤中的吸附和运移研究进展

介绍了国内外近年来对重要的污染元素汞和镉在土壤中吸附和运移方面的研究成果。评价土壤吸附重金属离子多运用Langmuir、Freundlich及Temkin三种等温吸附曲线。影响土壤吸附汞和镉的因素主要有pH值、有机质、氯离子、土壤组分、土壤类型、竞争吸附离子的参与等。汞的活动性较差，其迁移性质缺乏研究；土壤中镉的二价离子在粘土衬层内的迁移过程中，可生成难溶性沉淀物质，阻碍了液体的渗透，因而导致渗透系数比纯水还低。引用参考文献45篇。     

江汉平原旱地和水田土壤镉的吸附与解吸特征及影响因素

为揭示旱地和水田土壤镉的吸附解吸特征,以江汉平原黄豆地、棉花地以及水稻田土壤为研究对象,开展土壤镉的吸附动力学实验、等温吸附?解吸实验以及有机质的影响实验.结果表明:江汉平原土壤对镉的吸附是一个较为复杂的吸附动力学过程且以化学吸附为主,研究区土壤镉的初始吸附速率总体上表现为水田土壤大于旱地土壤;旱地土壤对Cd2+具有较...     

荷载对重塑煤体吸附特性的影响

碎软煤的完整原样制取困难,需要加工制成重塑煤体,为了研究不同压制荷载对煤体物性特征的影响,以重塑煤体为研究对象,基于低温液氮的孔隙测试实验和高压容量法的甲烷吸附实验,探讨不同成型荷载而成的重塑煤体的微小孔结构及其吸附特性的差异。结果表明:不同成型荷载压制而成的重塑煤体,其微孔和小孔的孔容随着成型荷载的增大而略微减少,孔比表面积随着成型荷载的增大而略微增加,总孔体积减少和孔比表面积增加的幅度不大;通过分形理论发现无论高压段还是低压段,孔隙结构具有明显的分形特征,且在高压段的分形维数普遍低于低压段,不同荷载压制而成的重塑煤体的分形维数差别不大;等温吸附线均符合第Ⅰ类等温吸附曲线,Langmuir模型适用于描述重塑煤体的等温吸附,成型荷载对煤的吸附常数有一定的影响,其对吸附常数b值的影响大于对a值的影响。研究不同成型荷载下重塑煤体的吸附特性,为不同条件下型煤制作及冷冻取心实验提供参考。      

不同煤阶深煤层含气量差异及其变化规律

基于Langmuir 等温吸附方程式,开展不同煤阶不同温压条件下等温吸附模拟实验,实验结果表明：在煤岩镜质组反 射率Ro<3.0%时,Langmuir 等温吸附曲线随煤阶、温度、压力升高表现出明显的分带性。随着煤阶的升高,煤吸附能力逐 渐增强。温度小于55℃时不同煤阶Langmuir 体积受温度影响较小,之后影响逐渐增大。低煤阶在12 MPa、中高煤阶在 15 MPa以前随压力增加Langmuir 体积增大明显。根据实测含气量外推法结合高温高压等温吸附实验建立了深煤层含气量数 学模型,显示煤层含气量随埋深呈现快速增加—缓慢增加—不增加—缓慢减小的变化规律,其中低煤阶临界深度介 于1400~1700 m,中高煤阶临界深度介于1500~1800 m。该含气量数学模型对预测深部煤层含气量变化规律及煤层气资源评 价提供基础依据。     

An experimental study of heavy metal attenuation and mobility in sandy loam soils

Column flow-through experiments reacting wastewater solutions with sandy loam soil samples were performed to study heavy metal attenuation by two soils with different physical and chemical properties. Reacted soil columns were leached with synthetic acid rain to study the mobility of attenuated heavy metals under leaching conditions. This study demonstrates that cation exchange, surface adsorption, chelation with solid organic material, and precipitation were the important attenuation mechanisms for the heavy metals (Cd, Cr, Cu, Mo, Ph, and Zn). Adsorption on soil hydrous oxide surfaces was the primary attenuation mechanism for Cd and Zn in both soils, and for Cu in a soil with low organic matter content. Wastewater solution pH is also an important factor that influences the retention of heavy metals. Cadmium, Cu, Cr, and Zn became mobile after prolonged application of spiked wastewater solution, either through saturation of soil adsorption sites or due to decreasing pH. Only Cr, Pb, and Mo, which are attenuated primarily through precipitation, show significant net retention by soil. Acid rain water removed heavy metals left in the column residual pore solution and weakly sorbed heavy metals in the soils, and has the ability to mobilize some strongly attenuated heavy metals, especially when the soil organic matter content is high. The results have important applications in predicting heavy metal mobility in contaminated soil, the disposal of acid mine drainage, and assessing the risks of landfall leachate leakage.     

Removal of cadmium and humic acid from aqueous solutions using surface modified nanozeolite A

The sorption of cadmium and humic acids from aqueous solutions using surface-modified nanozeolite A has been investigated under various examination conditions. The morphology of untreated and treated nanozeolite was studied under scanning electron microscope and transmission electron microscope. Isotherms of cadmium adsorption onto surface-modified nanozeolite A were studied at different pH, solid to liquid ratio, adsorbate concentration and interaction time. Kinetic and equilibrium studies were conducted and the equilibrium data have been analyzed using Langmuir and Freundlich isotherm models. The study revealed that experimental results were in agreement with the Freundlich model. The Langmuir monolayer adsorption capacity was found to be 1666.67 g cadmium and 6.75 g humic acid per gram of modified nanozeolite A, which is higher than that of reported value for other zeolites. The sorption ability was enhanced by surface modification and reduction in size and enabled the zeolite to adsorb cadmium. The adsorption of cadmium and humic acid on nanozeolite was found to be the highest at pH 6 and 3, respectively. Results showed that solid to liquid ratio and pH are the most important factors for cadmium and humic acid removal, respectively. Effect of competitive ions was studied and results showed that there is no competition between cadmium and humic acid sorption and presence of these ions.     

酸雨石等5种常用吸盐材料的盐碱土壤改良效果研究

以黑龙江省大庆市林甸县长青林场3个不同小区为实验地,分别采用酸雨石等5种吸盐材料对不同小区盐碱土壤进行改良,根据改良后土壤pH、导电率变化,对不同材料的盐碱土壤改良效果进行比较。研究表明,短期内吸盐速率:酸雨石活性炭腐熟牛粪沸石稻壳,长期吸盐量:酸雨石活性炭沸石稻壳腐熟牛粪,效果持久性为酸雨石最强,活性炭、沸石次之,稻壳较弱,腐熟牛粪最弱。酸雨石解碱能力最强,活性炭次之,沸石、牛粪、稻壳解碱能力较弱。因此,酸雨石在5种盐碱土改良剂中具有最强吸盐解碱能力。     

河北保定典型污灌区土壤Cu吸附特性研究

我国部分地区土壤污染形势严峻,主要表现为Cu等重金属元素严重超标。污水灌溉以及含Cu饲料过量使用等不合理的农业生产方式是导致Cu在耕地中富集的主要因素,严重威胁粮食安全和人类健康。以河北保定典型污灌区为研究区,通过静态吸附批量实验探究土壤吸附Cu的动力学和热力学特性。吸附动力学模型和等温吸附经验模型中得到的参数一致表明,表层土壤S1对Cu的吸附能力强于底部土壤S2。S1的有机质含量高于S2,提供了更多的表面吸附点位,这可能是导致土壤S1对Cu的吸附能力更强的原因之一。离子强度对土壤Cu吸附率的影响较小。溶液pH和溶解性有机物(DOM)含量对土壤Cu吸附率的影响明显,pH值与吸附量呈正相关,DOM浓度与吸附量呈负相关。由于土壤对pH有很强的缓冲能力,短时间的酸雨可能不会导致Cu的迁移。施用有机肥时,有机肥浸出液中高浓度的DOM可能会与Cu形成水溶性Cu-DOM络合物,促进Cu在土壤中的迁移,导致浅层地下水污染。     

承德市富硒土壤区镉的地球化学特征及生态风险评价

硒是人体必需的生命元素,开发富硒农产品是提升人体硒摄入的安全有效途径,富硒土地资源是开发富硒农产品的基础。然而,近年来全国开展的多目标地球化学调查发现,富硒土壤中重金属元素镉通常较高,不利于富硒土地开发利用,因此,研究富硒土壤区镉的地球化学特征和生态风险状况对于富硒土地开发具有重要的指导意义。文章对承德市富硒土壤区表层土壤中主要的重金属元素镉的地球化学特征及生态风险进行评价,旨在为承德市富硒土地开发利用提供科学依据。采用“七步提取法”研究了表层土壤镉的形态特征。同时,配套分析了苹果、玉米样品中的重金属元素镉的含量,以了解其生物有效性。结果显示:承德市富硒土壤区表层土壤镉在全区均较富集,在新积土和中性粗骨土、水田中显著富集。研究区圈定了4处镉轻度污染土壤,均在表层土壤镉的高值区。表层土壤镉形态平均含量大小顺序为:水溶态 < 离子交换态 < 强有机结合态 < 腐殖酸结合态 < 铁锰氧化物结合态 < 碳酸盐结合态 < 残渣态,生态风险相对较低。表层土壤镉未对苹果和玉米样品产生影响,苹果和玉米中镉均不超标。承德市富硒土壤区表层土壤镉的生态风险较低,暂不影响承德市富硒土地开发利用。     

西南表层岩溶带土壤中砷的迁移规律实验与模拟

岩溶地下河是我国西南地区的重要水源,工业生产过程中产生的砷污染物,除通过落水洞等直接进入并污染地下水外,还会在表层岩溶带溶缝、溶隙内吸附、滞留及富集,并在特定条件下再次迁移,成为"稳定次生污染源".以广西某砷污染事件为例,采用窄缝槽物理模型装置进行砷的动态吸附、解吸实验,并结合地球化学模拟研究砷污染物在表层岩溶带土壤中的迁移规律.实验结果显示表层岩溶带对砷的吸附以物理吸附（扩散过程）为主,相比吸附过程而言解吸速率则显得缓慢,而酸溶液相比去离子水可促进砷的解吸过程.地球化学模拟结果表明土壤矿物中以针铁矿对砷的吸附贡献最大,而酸溶液通过溶蚀针铁矿等矿物削弱对砷的吸附能力.因此在西南岩溶地区,表层岩溶带系统一旦纳入砷污染物,则解吸过程缓慢,易形成砷污染物的滞留、富集;而酸雨作用下砷的解吸、迁移过程加快,则会提高地下水系统的污染风险.      

成都经济区农业土壤Cd元素的解吸动力学

对不同酸雨条件下水稻土Cd释放的研究发现,吸附态Cd释放的过程可以分为快反应和慢反应2个阶段。采用常见的动力学方程和本文创建的反三角函数方程,对淋滤实验数据进行了拟合。结果表明,反三角函数方程对多种酸雨条件下水稻土吸附态Cd释放过程的拟合度最佳。此外,多项式方程也能较好地描述这一过程。     

Experimental simulation and dynamic model analysis of Cadmium(Cd) release in soil affected by rainfall leaching in a coal-mining area

In order to explore the influence of rainfall on the release of heavy metal Cadmium(Cd)in soil in a coal-mining area,soil column leaching experiments were carried out by simulating 3 types of rainfall(acid rain,normal rainfall,and actual rainfall)with 5 different pH values(4,5,6,6.7,7),and 65 groups of data about leachate pH value and Cd concentration were obtained respectively.The results indicate the general change rule of Cd concentration in leachate:(1)the easiness of Cd release is negatively correlated to the pH value of leaching solution and positively correlated the leaching amount;(2)leaching solution with lower pH values shows more obvious release stages.Leached by solution with different pH values,the release of Cd in soil ranks as follows:Acid rain group>normal rainfall group>actual rainfall group.In the first stage,the acidity of rainfall has a significant impact on the release of Cd in soil,but in the second stage,the release of Cd is alleviated due to the soil buffering.Among the four dynamic equations to simulate the release of Cd in soil,the modified Elovich equation can describe the process most accurately,with the highest coefficient of determination R2 of 0.9975.These results can serve as a reference for further study on the migration,transformation and enrichment of Cd in soil.     

Removal of heavy metal ions from aqueous solutions with multi-walled carbon nanotubes: Kinetic and thermodynamic studies

Multi-walled carbon nanotubes were used successfully for the removal of Copper(II), Lead(II), Cadmium(II), and Zinc(II) from aqueous solution. The results showed that the % adsorption increased by raising the solution temperature due to the endothermic nature of the adsorption process. The kinetics of Cadmium(II), Lead(II), Copper(II), and Zinc(II) adsorption on Multi-walled carbon nanotubes were analyzed using the fraction power function model, Lagergren pseudo-first-order, pseudo-second-order, and Elovich models, and the results showed that the adsorption of heavy metal ions was a pseudo-second-order process, and the adsorption capacity increased with increasing solution temperature. The binding of the metal ions by the carbon nanotubes was evaluated from the adsorption capacities and was found to follow the following order: Copper(II) > Lead(II) > Zinc(II) > Cadmium(II). The thermodynamics parameters were calculated, and the results showed that the values of the free energies were negative for all metals ions, which indicated the spontaneity of the adsorption process, and this spontaneity increased by raising the solution temperature. The change in entropy values were positives, indicating the increase in randomness due to the physical adsorption of heavy metal ions from the aqueous solution to the carbon nanotubes’ surface. Although the enthalpy values were positive for all metal ions, the free energies were negative, and the adsorption was spontaneous, which indicates that the heavy metal adsorption of Multi-walled carbon nanotubes was an entropy-driving process.