Effect of pH on transport of Pb（2＋）,Mn（2＋）,Zn（2＋）and Ni（2＋） through lateritic soil： Column experiments and transport modeling

This study investigated the e ects of pH on the transport of Pb2+, Mn2+, Zn2+ and Ni2+ through lateritic soil columns. Model results by fitting the symmetric breakthrough curves (BTCs) of bromide (Br??) with CXTFIT model suggested that physical non-equilibrium processes were absent in the columns. The heavy metal BTCs were, however, asymmetrical and exhibited a tailing phenomenon, indicating the presence of chemical non-equilibrium processes in the columns. The retardation factors of Pb2+ were the largest of the four metal ions at both pH 4.0 (33.3) and pH 5.0 (35.4). The use of Langmuir isotherm parameters from batch studies with HYDRUS-1D did not predict the BTCs well. Rather the two-site model (TSM) described the heavy metal BTCs better than the equilibrium linear/nonlinear Langmuir model. The fraction of instantaneous sorption sites ( f ) of all four metal ions on the lateritic soil was consistently about 30%–44% of the total sorption sites.     

Bio-remediation of acephate–Pb(II) compound contaminants by Bacillus subtilis FZUL-33

Removal of Pb~(2+)and biodegradation of organophosphorus have been both widely investigated respectively. However, bio-remediation of both Pb~(2+)and organophosphorus still remains largely unexplored. Bacillus subtilis FZUL-33, which was isolated from the sediment of a lake, possesses the capability for both biomineralization of Pb~(2+)and biodegradation of acephate. In the present study, both Pb~(2+)and acephate were simultaneously removed via biodegradation and biomineralization in aqueous solutions.Batch experiments were conducted to study the influence of p H, interaction time and Pb~(2+)concentration on the process of removal of Pb2+. At the temperature of 25°C, the maximum removal of Pb~(2+)by B. subtilis FZUL-33 was 381.31 ± 11.46 mg/g under the conditions of p H 5.5, initial Pb~(2+)concentration of 1300 mg/L, and contact time of 10 min. Batch experiments were conducted to study the influence of acephate on removal of Pb~(2+)and the influence of Pb2+on biodegradation of acephate by B. subtilis FZUL-33. In the mixed system of acephate–Pb2+, the results show that biodegradation of acephate by B. subtilis FZUL-33 released PO43+, which promotes mineralization of Pb2+. The process of biodegradation of acephate was affected slightly when the concentration of Pb2+was below 100 mg/L. Based on the results, it can be inferred that the B. subtilis FZUL-33 plays a significant role in bio-remediation of organophosphorus-heavy metal compound contamination.     

New insight into adsorption characteristics and mechanisms of the biosorbent from waste activated sludge for heavy metals

The adsorption characteristics and mechanisms of the biosorbent from waste activated sludge were investigated by adsorbing Pb2+and Zn2+in aqueous single-metal solutions. A p H value of the metal solutions at 6.0 was beneficial to the high adsorption quantity of the biosorbent. The optimal mass ratio of the biosorbent to metal ions was found to be 2. A higher adsorption quantity of the biosorbent was achieved by keeping the reaction temperature below 55°C. Response surface methodology was applied to optimize the biosorption processes, and the developed mathematical equations showed high determination coefficients(above 0.99 for both metal ions) and insignificant lack of fit(p = 0.0838 and 0.0782 for Pb2+and Zn2+, respectively). Atomic force microscopy analyses suggested that the metal elements were adsorbed onto the biosorbent surface via electrostatic interaction. X-ray photoelectron spectroscopy analyses indicated the presence of complexation(between –NH2,-CN and metal ions) and ion-exchange(between –COOH and metal ions). The adsorption mechanisms could be the combined action of electrostatic interaction, complexation and ion-exchange between functional groups and metal ions.     

Simultaneous adsorption of lead and cadmium on MnO2-loaded resin

MnO2-loaded D301 weak basic anion exchange resin has been used as adsorbent to simultaneously remove lead and cadmium ions from aqueous solution. The e ects of adsorbent dosage, solution pH and the coexistent ions on the adsorption were investigated. Experimental results showed that with the adsorbent dosage more than 0.6 g/L, both Pb2+ and Cd2+ were simultaneously removed at pH range 5–6. Except for HPO4 2??, the high concentration coexistent ions such as Na+, K+, Cl??, NO3??, SO4 2?? and HCO3??, showed no significant e ect on the removal e ciency of both Pb2+ and Cd2+ under the experimental conditions. The coexistence of Mg2+, Ca2+ caused the reduction of Cd2+ removal, but not for Pb2+. The adsorption equilibrium for Pb2+ and Cd2+ could be excellently described by the Langmuir isotherm model with R2 > 0.99. The maximum adsorption capacity was calculated as 80.64 mg/g for Pb2+ and 21.45 mg/g for Cd2+. The adsorption processes followed the pseudo first-order kinetics model. MnO2-loaded D301 resin has been shown to have a potential to be used as an e ective adsorbent for simultaneous removal of lead and cadmium ions from aqueous solution.     

Removal of Cd2+ from water by Friedel’s salt (FS: 3CaO.Al2O3·CaCl2·10H2O): Sorption characteristics and mechanisms

The development of low-cost and efficient new mineral adsorbents has been a hot topic in recent years. In this study, Friedel’s salt (FS:3CaO·A12O3 ·CaCl2 ·10H2O), a hexagonal layered inorganic absorbent, was synthesized to remove Cd2+ from water. The adsorption process was simulated by Langmuir and Freundlich models. The adsorption mechanism was further analyzed with TEM, XRD, FT-IR analysis and monitoring of metal cations released and solution pH variation. The results indicated the adsorbent FS had an outstanding ability for Cd(Ⅱ) adsorption. The maximum adsorption capacity of the FS for Cd(Ⅱ) removal can reach up to 671.14 mg/g. The nearly equal numbers of Cd2+ adsorbed and Ca2+ released demonstrated that ion-exchange (both surface and inner) of the FS for Cd(Ⅱ) played an important role during the adsorption process. Furthermore, the surface of the FS after adsorption was microscopically disintegrated while the inner lamellar structure was almost unchanged. The behavior of Cd(Ⅱ) adsorption by FS was significantly affected by surface reactions. The mechanisms of Cd2+ adsorption by the FS mainly included surface complexation and surface precipitation. In the present study, the adsorption process was fitted better by the Langmuir isotherm model (R2 = 0.9999) than the Freundlich isotherm model (R2 = 0.8122). Finally, due to the high capacity for ion-exchange on the FS surface, FS is a promising layered inorganic adsorbent for the removal of Cd(Ⅱ) from water.     

Removal of Pb(II) from aqueous solution by hydrous manganese dioxide: Adsorption behavior and mechanism

Hydrous manganese dioxide (HMO) synthesized by redox of potassium permanganate and hydrogen peroxide was used as an adsorbent for Pb(Ⅱ) removal.The specific surface area,pore volume and BJH pore diameter of the HMO were 79.31m2/g,0.07cm3/g and 3.38 nm,respectively.The adsorption equilibrium at 298K could be well described by the Langmuir isotherm equation with q max value of 352.55mg/g.The negative values of G and the positive values of H and S indicated the adsorption process was spontaneous and endothermic.The pseudo second-order equation could best fit the adsorption data.The value of the calculated activation energy for Pb(Ⅱ) adsorption onto the HMO was 38.23 kJ/mol.The uptake of Pb(Ⅱ) by HMO was correlated with increasing surface hydroxyl group content and the main adsorbed speciation was PbOH+.The final chemical state of Pb(Ⅱ) on the surface of HMO was similar to PbO.HMO was a promising candidate for Pb(Ⅱ) removal from aqueous solution.     

Chemodynamics of heavy metals in long-term contaminated soils：Metal speciation in soil solution

The concentration and speciation of heavy metals in soil solution isolated from long-term contaminated soils were investigated. The soil solution was extracted at 70% maximum water holding capacity (MWHC) after equilibration for 24 h. The free metal concentrations (Cd2+, Cu2+, Pb2+, and Zn2+) in soil solution were determined using the Donnan membrane technique (DMT). Initially the DMT was validated using artificial solutions where the percentage of free metal ions were significantly correlated with the percentages predicted using MINTEQA2. However, there was a significant difference between the absolute free ion concentrations predicted by MINTEQA2 and the values determined by the DMT. This was due to the significant metal adsorption onto the cation exchange membrane used in the DMT with 20%, 28%, 44%, and 8% mass loss of the initial total concentration of Cd, Cu, Pb, and Zn in solution, respectively. This could result in a significant error in the determination of free metal ions when using DMT if no allowance for membrane cation adsorption was made. Relative to the total soluble metal concentrations the amounts of free Cd2+ (3%–52%) and Zn2+ (11%–72%) in soil solutions were generally higher than those of Cu2+ (0.2%–30%) and Pb2+ (0.6%–10%). Among the key soil solution properties, dissolved heavy metal concentrations were the most significant factor governing free metal ion concentrations. Soil solution pH showed only a weak relationship with free metal ion partitioning coefficients (Kp) and dissolved organic carbon did not show any significant influence on Kp.     

Effects of metal cations on sorption-desorption of p-nitrophenol onto wheat ash

The mutual e ects of metal cations (Cu2+, Pb2+, Zn2+, and Cd2+) and p-nitrophenol (NP) on their adsorption desorption behavior onto wheat ash were studied. Results suggested that Cu2+, Pb2+, and Zn2+ diminished the adsorption and increased the desorption of NP remarkably, while Cd2+ had no such e ect. In contrast, NP diminished the adsorption of Cu2+, Pb2+, and Zn2+ onto ash, however, this suppression e ect depended on the initial concentrations of metal cations. NP had no e ect on Cd2+ adsorption on ash. Fourier transform infrared (FT-IR) and X-ray absorption spectroscopic (XAS) studies suggested the following mechanisms responsible for the metal suppression e ect on NP adsorption: (1) large hydrated Cu2+, Pb2+, and Zn2+ shells occupied the surface of ash and prevent nonspecific adsorption of NP onto ash surface; (2) Cu2+, Pb2+, and Zn2+ may block the micropores of ash, resulting in decreased adsorption of NP; (3) complexation of Cu2+, Pb2+, and Zn2+ was likely via carboxyl, hydroxylic and phenolic groups of wheat ash and these same groups may also react with NP during adsorption. As a “soft acid”, Cd2+ is less e cient in the complexation of oxygencontaining acid groups than Cu2+, Pb2+, and Zn2+. Thus, Cd2+ had no e ect on the adsorption of NP on wheat ash.     

Predicting heavy metals’ adsorption edges and adsorption isotherms on MnO2 with the parameters determined from Langmuir kinetics

Although surface complexation models have been widely used to describe the adsorption of heavy metals, few studies have verified the feasibility of modeling the adsorption kinetics,edge, and isotherm data with one p H-independent parameter. A close inspection of the derivation process of Langmuir isotherm revealed that the equilibrium constant derived from the Langmuir kinetic model, K S-kinetic, is theoretically equivalent to the adsorption constant in Langmuir isotherm, K S-Langmuir. The modified Langmuir kinetic model(MLK model) and modified Langmuir isotherm model(MLI model) incorporating p H factor were developed. The MLK model was employed to simulate the adsorption kinetics of Cu(II), Co(II), Cd(II), Zn(II) and Ni(II) on Mn O2 at p H 3.2 or 3.3 to get the values of K S-kinetic. The adsorption edges of heavy metals could be modeled with the modified metal partitioning model(MMP model), and the values of K S-Langmuir were obtained. The values of K S-kinetic and K S-Langmuir are very close to each other, validating that the constants obtained by these two methods are basically the same. The MMP model with K S-kinetic constants could predict the adsorption edges of heavy metals on Mn O2 very well at different adsorbent/adsorbate concentrations. Moreover, the adsorption isotherms of heavy metals on Mn O2 at various p H levels could be predicted reasonably well by the MLI model with the K S-kinetic constants.     

Material conversion from paper sludge ash in NaOH solution to synthesize adsorbent for removal of Pb^2＋, NH^4＋ and PO4^3- from aqueous solution

Material conversion from paper sludge ash (PSA) in NaOH solution was attempted to synthesize the adsorbent for removal of inorganic pollutants, such as Pb2+, NH4 + and PO4 3?? from aqueous solution. PSA of 0.5 g was added into 10 mL of 3 mol/L NaOH solution, and then heated at 80, 120, and 160°C for 6–48 hr to obtain the product. PSA mainly composed of two crystalline phases, gehlenite (Ca2Al2SiO7) and anorthite (CaAl2Si2O8), and amorphous phase. Hydroxysodalite (Na6Al6Si6O24 8H2O) was formed at 80°C, and anorthite dissolved, whereas gehlenite remained una ected. Katoite (Ca3Al2SiO4(OH)8) was formed over 120°C, and hydroxycancrinite (Na8(OH)2Al6Si6O24 2H2O) was formed at 160°C, due to the dissolution of both gehlenite and anorthite. Specific surface areas of the products were almost same and were higher than that of raw ash. Cation exchange capacities (CECs) of the products were also higher than that of raw ash, and CEC obtained at lower temperature was higher. Removal abilities of products for Pb2+, NH4 +, and PO4 3?? were higher than that of raw ash.With increasing reaction temperature, the removal e ciencies of Pb2+ and NH4 + decreased due to the decrease of CEC of the product, while removal e ciency for PO4 3?? was almost same. The concentrations of Si and Al in the solution and the crystalline phases in the solid during the reaction explain the formation of the product phases at each temperature.     

Relation of lead adsorption on birnessites with di erent average oxidation states of manganese and release of Mn2+/H+/K+

The characteristics of Pb2+ adsorption on the surface of birnessites with di erent average oxidation states (AOS) of Mn, synthesized under acidic and alkali conditions, were investigated. The results indicated that the amount of adsorbed Pb2+ increased with the increase of Mn AOS in birnessites. The amount of Pb2+ adsorbed positively correlated with the amount of released Mn2+, H+, and K+ (r = 0.9962 > 0.6614, n = 14, = 0.01). The released Mn2+, H+, and K+ were derived mostly from the corresponding cations adsorbed on the vacant sites. The maximum amount of adsorbed Pb2+ increased with the increasing vacant cation sites, leading to an increase of the total amount of released Mn2+, H+, and K+, and the increased likelihood for two Pb2+ adsorbed in the region of one side of a vacant site.     

水钠锰矿的锰氧化度与Pb~(2+)吸附量的关系

研究水钠锰矿对重金属离子的吸附,其结构中八面体空穴特点与重金属离子吸附的关系是人们关注的热点.采用酸性和碱性2种介质条件合成了具有不同锰氧化度的2个系列水钠锰矿,研究了它们的锰氧化度(average oxidation state of Mn, AOS)与其d110面网间距和Pb2+的最大吸附量的关系,以及Pb2+吸附量与Mn2+、H+和K+释放量的关系.结果表明,同系列的水钠锰矿具有相似的晶体形貌,它们的锰氧化度与其d110面网间距呈极显著的负相关(r =-0.9035<-0.6614,n=14,α=0.01),而与Pb2+的最大吸附量呈极显著的正相关(r=0.9779>0.6614,n=14,α=0.01),供试水钠锰矿锰氧化度的高低表观上反映了结构中八面体空穴数量的多少,水钠锰矿随着锰氧化度的提高,导致其结构中的八面体空穴数增多,对Pb2+的吸附容量增大,八面体空穴数量对Pb2+的吸附量的大小起着非常重要的作用.Pb2+的吸附量与吸附过程中Mn2+、H+和K+的释放量之和呈极显著的正相关(r = 0.9962 > 0.6614,n = 14,α = 0.01),Pb2+吸附过程中伴随的Mn2+、H+和K+的释放主要来自于水钠锰矿结构中八面体空穴处吸附的相应阳离子.吸附前Mn2+,Mn3+与H+、K+占据水钠锰矿结构中八面体空穴上下方位点的相对多少受水钠锰矿的锰氧化度高低的影响,锰氧化度低时,八面体空穴上下方位点吸附Mn2+、Mn3+较多,吸附的H+、K+则较少,反之亦然.     

水钠锰矿的Mn（Ⅲ）分布及Na4P2O7溶液处理对其铅吸附性能的影响

以深入理解水钠锰矿结构中低价锰离子的含量及分布对其铅吸附性能的影响为目的,通过不同pH（pH为2、4、5）的焦磷酸钠溶液络合浸提酸性水钠锰矿结构中的Mn（Ⅱ）和Mn（Ⅲ）,研究了浸提锰离子的形态、含量、矿物的锰平均氧化度和Pb2＋的吸附量及其伴随Mn2＋、H＋释放量的变化.结果表明,锰平均氧化度为3.670的酸性水钠锰...     

Zn2+和Mn2+处理水钠锰矿后对Pb2+吸附量的影响

分别采用Zn2+和Mn2+处理锰平均氧化度较高的水钠锰矿,对比研究了经不同浓度的Zn2+和Mn2+处理后矿物的锰平均氧化度、d110面网间距、对Pb2+的最大吸附量以及吸附过程中Zn2+和Mn2+的最大释放量等的变化.同时,通过Zn2+和Mn2+与水钠锰矿表面反应行为的不同,进一步明确矿物结构中的八面体空穴数量与重金属吸附量的关系.研究结果表明,水钠锰矿经Zn2+和Mn2+分别处理后,矿物类型未改变,并具有相似的晶体形貌.Zn2+溶液处理水钠锰矿时,随着Zn2+浓度的增大,水钠锰矿的锰平均氧化度和d110面网间距不变,说明结构中空穴数量未改变,Zn2+通过占据部分吸附点位,导致其对Pb2+的最大吸附量从3190 mmol·kg-1减少为2030 mmol·kg-1.而Mn2+溶液处理水钠锰矿时,大多数Mn2+被氧化为Mn3+,这些Mn3+部分位于八面体空穴上下方的吸附位点,部分进入八面体空穴中.随着加入的Mn2+浓度增大,Mn2+被氧化为Mn3+而进入八面体空穴的数量增多,锰平均氧化度减小,d110面网间距从0.14160 nm增大至0.14196 nm,说明结构中空穴数量减少,对Pb2+的最大吸附量从3190 mmol·kg-1减少至1332 mmol·kg-1.对比研究结果表明,水钠锰矿结构中的八面体空穴数量对Pb2+的吸附量的大小起着非常重要的作用.     

不同结构水钠锰矿催化氧化对苯二酚腐殖化程度的差异及其原因分析

本文合成了一系列不同氧化度的酸性和碱性水钠锰矿,以对苯二酚作为腐殖质形成的前驱物,分析水钠锰矿矿物类型和亚结构变化对对苯二酚腐殖化程度的影响。取得的主要结果有:水钠锰矿的矿物类型和亚结构(锰氧化度、八面体空位、H+、Mn4+和Mn3+含量)对对苯二酚的腐殖化程度具有重要的影响,且矿物类型的影响大于同种矿物不同亚结构产生的影响。酸性水钠锰矿比碱性水钠锰矿含有更多的H+,导致酸性水钠锰矿比碱性水钠锰矿具有更高的氧化容量,反应达到平衡后,对苯二酚腐殖化程度更高。因此,水钠锰矿物中H+含量对对苯二酚腐殖化程度的影响要大于矿物中Mn4+和Mn3+含量的影响。同种类型水钠锰矿氧化度越高,得电子量将越多,氧化容量越大,反应达到平衡后,对苯二酚腐殖化程度越高。     

水钠锰矿对几种重金属离子的吸附及其与锰氧化度和吸附位点的关系

矿物表面的吸附位点类型与数量决定了其对重金属离子的吸附特性,但氧化锰矿物的结构变化对表面位点,以及吸附特性的影响并不清楚.本研究通过X-射线衍射（XRD）、X-射线光电子能谱（XPS）、等温吸附等技术和方法对比分析了不同锰氧化度（AOS）酸性水钠锰矿对Pb2＋、Cu2＋、Zn2＋、Cd2＋的吸附特点,并探讨了水钠锰矿锰...     

Mn(Ⅲ)在水钠锰矿氧化Cr(Ⅲ)反应中的作用

环境中的氧化锰矿物是可氧化Cr(Ⅲ)的唯一天然无机氧化剂,氧化锰矿物与Cr(Ⅲ)相互作用的反应速率与机制备受关注.本研究以水钠锰矿为对象,采用批量动力学方法研究了其结构中Mn(Ⅲ)在氧化Cr(Ⅲ)反应中的作用及动力学特点.结果表明,水钠锰矿氧化Cr(Ⅲ)符合准一级动力学方程,表观速率常数Kobs为0.0313 min-1,以Na4P2O7预处理水钠锰矿可络合出结构中的部分Mn(Ⅲ),使其Mn的平均氧化度升高.当处理Na4P2O7浓度为10、20、50 mmol/L时,其Mn氧化度由3.50升高至3.63、3.73和3.78,处理后的水钠锰矿对Cr(Ⅲ)的平衡氧化率增加,但初始氧化速率变化并不明显,其相应表观速率常数分别为0.0351、0.0325和0.0309 min-1.水钠锰矿氧化Cr(Ⅲ)的反应历程中,Mn(Ⅳ)→Mn(Ⅲ)的电子转移过程生成的Mn(Ⅲ)显著影响水钠锰矿氧化Cr(Ⅲ)的速率.当新生成Mn(Ⅲ)被Na4P2O7络合后,反应速率降低45%~88%,且水钠锰矿的氧化度较低时,结构中Mn(Ⅲ)含量高,反应中被络合的新生态Mn(Ⅲ)多,反应速率降低幅度相对较大.因此,反应新生成的Mn(Ⅲ)具有较高的反应活性和较快的电子转移速率,而Mn(Ⅳ)→Mn(Ⅲ)的电子转移速率较慢,可能为水钠锰矿氧化Cr(Ⅲ)的反应速率控制步骤.     

Coordination geometry of Zn~(2+) on hexagonal turbostratic birnessites with different Mn average oxidation states and its stability under acid dissolution

Hexagonal turbostratic birnessite,with the characteristics of high contents of vacancies,varying amounts of structural and adsorbed Mn~(3+),and small particle size,undergoes strong adsorption reactions with trace metal(TM)contaminants.While the interactions of TM,i.e.,Zn~(2+),with birnessite are well understood,the effect of birnessite structural characteristics on the coordination and stability of Zn~(2+)on the mineral surfaces under proton attack is as yet unclear.In the present study,the effects of a series of synthesized hexagonal turbostratic birnessites with different Mn average oxide states(AOSs)on the coordination geometry of adsorbed Zn~(2+)and its stability under acidic conditions were investigated.With decreasing Mn AOS,birnessite exhibits smaller particle sizes and thus larger specific surface area,higher amounts of layer Mn~(3+)and thus longer distances for the first Mn\O and Mn\Mn shells,but a low quantity of available vacancies and thus low adsorption capacity for Zn~(2+).Zn K-edge EXAFS spectroscopy demonstrates that birnessite with low Mn AOS has smaller adsorption capacity but more tetrahedral Zn(~(IV)Zn)complexes on vacancies than octahedral(~(VI)Zn)complexes,and Zn~(2+)is more unstable under acidic conditions than that adsorbed on birnessite with high Mn AOS.High Zn~(2+)loading favors the formation of~(VI)Zn complexes over~(IV)Zn complexes,and the release of Zn~(2+)is faster than at low loading.These results will deepen our understanding of the interaction mechanisms of various TMs with natural birnessites,and the stability and thus the potential toxicity of heavy metal pollutants sequestered by engineered nano-sized metal oxide materials.     

青霉菌和镰刀菌对重金属Cd~(2+)、Cu~(2+)、Zn~(2+)和Pb~(2+)的吸附特性

研究了青霉菌和镰刀菌对重金属Cd2+、Cu2+、Zn2+和Pb2+的吸附特性,探讨了复合重金属和不同培养基对菌株吸附能力的影响.同时,采用察氏液体培养基(CDM)和马铃薯葡萄糖培养基(PDB)接种菌株,对不同种类和浓度的重金属进行吸附实验.结果表明,青霉菌和镰刀菌对Cd2+、Cu2+和Zn2+的吸附率随金属浓度的升高而下降,吸附量随金属浓度的增加先增大后减小;当浓度增加到较高值(300mg·L-1)时,Pb2+的吸附率开始下降,吸附量先逐渐增加后变化不大.菌丝体对重金属的吸附能力表现出一定的差异性,对Pb2+的吸附率和吸附量明显高于其他3种金属,CDM培养青霉菌对300mg·L-1Pb2+的最大吸附量达到34.80mg·g-1.多种重金属的复合抑制了菌丝体对重金属离子的吸附.不同菌丝体对复合重金属的吸附量差异性较大,PDB培养混合菌体对重金属离子的吸附率和吸附量均较大,并有明显的促进作用.CDM培养菌丝体对Pb2+的吸附量均高于PDB培养菌丝体.     

市政污泥生物碳对重金属的吸附特性

采用市政污泥在300℃缺氧条件下制得污泥生物碳,研究了污泥生物碳添加量、溶液pH及吸附反应时间对溶液中Pb2+、Cu2+、Zn2+吸附效果的影响,并分析了各因素影响机制及污泥生物碳对重金属的吸附机理. 结果表明,污泥生物碳对溶液中重金属的去除率与重金属水合离子半径呈负相关,随着污泥生物碳添加量的增加,溶液中重金属的去除率不断增加,但单位吸附量总体上呈下降趋势. 重金属吸附量随溶液pH的增加而增大,当溶液初始pH为6.00时,污泥生物碳对溶液中Pb2+、Cu2+和Zn2+的吸附量最大,分别达42.941、25.769和12.484mg/g. 伪二级动力学方程可有效描述溶液中重金属离子在生物碳上的吸附过程,重金属在污泥生物碳表面的吸附主要受化学反应控制,Pb2+、Cu2+和Zn2+的平衡吸附量分别为39.747、6.849和10.004mg/g,达到吸附平衡的时间为Pb2+＞Zn2+＞Cu2+.