Combined toxicity of copper and cadmium to six rice genotypes （Oryza sativa L.）

Accumulation of copper (Cu) and cadmium (Cd) in six rice cultivars (94D-22, 94D-54, 94D-64, Gui630, YY-1 and KY1360) was evaluated through exposure to heavy metal contamination (100 mg/kg Cu, 1.0 mg/kg Cd, and 100 mg/kg Cu + 1.0 mg/kg Cd) in a greenhouse. The dry weight of shoot and root, concentrations of Cu and Cd in plant tissues and the Cu, Cd, P, Fe concentrations in the root surface iron plaques were analyzed eight weeks later after treatment. The results indicated that the plant biomass was mainly determined by rice genotypes, not Cu and Cd content in soil. Separated treatment with Cu/Cd increased each metal level in shoot, root and iron plaques. Soil Cu enhanced Cd accumulation in tissues. In contrast, Cu concentrations in shoot and root was unaffected by soil Cd. Compared to single metal contamination, combined treatment increased Cd content by 110.6%, 77.0% and 45.2% in shoot, and by 112.7%, 51.2% and 18.4% in root for Gui630, YY-1 and KY1360, respectively. The content level of Cu or Cd in root surface iron plaques was not affected by their soil content. Cu promoted Fe accumulation in iron plaques, while Cd has no effect on P and Fe accumulation in it. The translocation of Cu and Cd from iron plaques to root and shoot was also discussed. These results might be beneficial in selecting cultivars with low heavy metal accumulation and designing strategies for soil bioremediation.     

Removal of heavy metals from a contaminated soil using tartaric acid

This study reports the feasibility of remediation of a heavy metal （HM） contaminated soil using tartaric acid, an environmentally-friendly extractant. Batch experiments were performed to test the factors influencing remediation of the HM contaminated soil. An empirical model was employed to describe the kinetics of riM dissolution/desorption and to predict equilibrium concentrations of HMs in soil leachate. The changes of HMs in different fractions before and after tartaric acid treatment were also investigated. Tartaric acid solution containing HMs was regenerated by chestnut shells. Results show that utilization of tartaric acid was effective for removal of riMs from the contaminated soil, attaining 50%-60% of Cd, 40%-50% of Pb, 40%-50% of Cu and 20%-30% of Zn in the pH range of 3.5-4.0 within 24 h. Mass transfer coefficients for cadmium （Cd） and lead （Pb） were much higher than those for copper （Cu） and zinc （Zn）. Sequential fractionations of treated and untreated soil samples showed that tartaric acid was effective in removing the exchangeable, carbonate fractions of Cd, Zn and Cu from the contaminated soil. The contents of Pb and Cu in Fe-Mn oxide fraciton were also significantly decreased by tartaric acid treatment. One hundred milliliters of tartaric acid solution containing HMs could be regenerated by 10 g chestnut shells in a batch reactor. Such a remediation procedure indicated that tartaric acid is a promising agent for remediation of HM contaminated soils. However, further research is needed before the method can be practically used for in situ remediation of contaminated sites.     

深圳市城市绿地土壤中重金属的含量及化学形态分布

对深圳市中心区城市绿地表层土壤(0-20cm)中Cu,Zn,Pb和Cd的含量、化学形态分布和迁移性进行研究.结果表明,土壤中Cu,Zn,Pb和Cd的含量分别为6.4-188.2(26.3)mg·kg-1,34.9-284.8(69.1)mg·kg-1,15.2-245.5(47.2)mg·kg-1和0.01-3.48(0.47)mg·kg-1.道路绿化带土壤中Cu,Zn和Pb的平均含量最高,在公园绿地土壤中Cd的平均含量最高.分别有75.6%,87.0%,98.8%和98.8%的土壤中Cu,Zn,Pb和Cd的含量超过广东省赤红壤的背景值,重金属在土壤中呈现明显的富集特征.土壤中Cu,Zn和Cd以残渣态所占比例最高,Pb以铁锰氧化物结合态最高.随着土壤中Cu,Zn,Pb和Cd含量的增加其残渣态所占比例降低,铁锰氧化物结合态或交换态所占比例增加,重金属活性增大.土壤中Cd迁移能力最强,迁移能力依次为Cd>Zn>Pb和Cu.     

Zn,Cu和Ni污染土壤中重金属的化学固定

利用化学固定剂处理被污泥中Zn,Cu和Ni污染的土壤,研究不同化学药剂对重金属离子的固定技术.结果表明,石灰、硫化物和硅酸盐对Zn都有较好的稳定效果,硫化物对Cu的稳定效果较好,硅酸盐和石灰对Ni的稳定效果较好;对于被Zn,Cu和Ni污染的土壤,混合药剂对重金属污染物的固定效果最佳.研究表明通过调解系统的pH和生成稳定化合物形态使土壤中Zn,Cu和Ni得以固定.通过硫化物 石灰化学固定处理,固定前后Zn,Cu和Ni的不稳定形态含量分别减少了69%,56%和59%.     

三江平原小叶章湿地土壤硫的组成与垂直分布

以三江平原小叶章湿地为对象,对比研究了典型草甸小叶章湿地和沼泽化草甸小叶章湿地土壤硫的组成与垂直分布特征.结果表明,在2种小叶章湿地类型中,土壤总硫含量分别为303.39～520.83和303.74～1 219.81 mg·kg-1,平均值为391.62和513.03 mg·kg-1,均低于世界平均土壤硫含量(700 mg·kg-1).硫主要富集在土壤表层,且主要以有机硫形式存在,有机硫占总硫比例约为90%,而在有机硫中,则以碳键硫所占比例最大,占总硫比例分别为45.34%和37.24%.沼泽化草甸小叶章湿地土壤各形态硫含量及其变异性均高于典型草甸小叶章湿地.在2种湿地土壤中各形态硫都具有明显的垂直分布特征和变异性.土壤有机质含量是影响硫含量的重要因素,同时也受到土壤各粒级含量的影响,并且土壤各形态硫含量之间存在一定的相关关系.     

模拟酸雨对土壤酸性磷酸酶活性的影响及机理

通过恒温恒湿连续培养的方法,研究了外源酸雨对土壤pH值、酸性磷酸酶活性的影响,同时运用紫外差光谱和荧光光谱对其机理进行了探讨.结果表明,酸雨通过改变土壤pH值而影响酶活性,pH6.66的近中性土壤酶活性呈现激活-抑制的变化过程;而pH4.61的酸性土壤酶活性持续下降.溶液构象研究表明,pH值是通过改变酶的肽链构象、氨基酸残基微环境而影响其活性的.     

改性黏土絮凝海洋原甲藻对水体中氮、磷的影响研究

通过对比研究典型有害微藻海洋原甲藻(Prorocentrum micans Ehrenberg)自然消亡(A1组)及改性黏土絮凝(A2组)两种体系,考察两体系中氮、磷等主要水质因子的变化情况.结果表明,改性黏土能有效去除P. micans并影响其后期生长状态,0.4g/L改性黏土添加3.5h后去除率可达60%以上,且藻密度无二次增长.改性黏土絮凝藻华过程中能有效去除水体营养元素, A2组DIP和DIN较A1组分别降低85%和35%.另外,添加改性黏土对水体有机氮、磷影响值得关注,第33d A2组TON和TOP较A1组分别减少约120, 6μmol/L. 改性黏土对有机氮、磷存在一定的埋存保护作用,通过吸附絮凝、螯合等作用使有机氮、磷脱离水体系统,而自然消亡体系中的微藻消亡后将通过分解、矿化等过程快速进入水体参与再循环.该研究系统阐述了改性黏土絮凝P. micans对水体营养环境的影响,以期为现场治理提供理论支持.     

中晚全新世六盘山流域土壤侵蚀的湖泊沉积记录

流域土壤侵蚀是流域水文—气候—生态的集中表现之一,对生态、环境等有着重大影响,重建过去流域土壤侵蚀强度对理解区域人类活动具有重要意义.本文选取黄土高原西南部高山湖泊——六盘山天池沉积岩芯为研究对象,基于XRF岩芯元素数据分析,结合可靠的AMS 14C年代序列,重建了中晚全新世以来六盘山流域土壤侵蚀强度变化记录.结果显示:5570?—?1600 cal BP,流域土壤侵蚀整体较强,侵蚀强度逐渐减弱,其主要受控于降水变化,也受植被覆盖等因素的影响;随着晚全新世气候逐渐变干,1600 cal BP之后的侵蚀强度整体弱于前一时期,此时段由于人类活动的显著影响,加剧了流域的土壤侵蚀.太阳辐射可能是研究区土壤侵蚀强度变化的初始驱动力,ENSO通过驱动亚洲季风变化影响区域降水,进而直接影响流域土壤侵蚀的强度变化.     

坡缕石黏土污泥对水相中亚甲基蓝吸附研究

利用坡缕石黏土污泥(从木质素磺酸钠废水中得到)和酸化的坡缕石黏土(1mol/L盐酸)作为吸附剂对水相中的亚甲基蓝进行吸附研究,并利用透射电镜(TEM)、红外光谱(FT-IR)、X-射线衍射(XRD)及Zeta电位分析对两种吸附剂的结构及表面电性进行了表征.结果表明:当吸附剂用量为10mg,温度为30℃时,1mol/L盐酸酸化的坡缕石黏土最大吸附量为97.50mg/g,坡缕石黏土污泥最大吸附量为98.7mg/g.选取坡缕石黏土污泥作为最佳吸附剂,对污泥吸附亚甲基蓝的吸附等温线、吸附热力学及吸附动力学模型进行了研究,结果显示:此吸附过程为自发吸热过程,吸附等温线更符合Langmuir模型,吸附动力学符合准二级动力学模型.     

天然黏土联合磷肥对农田土壤镉铅污染原位钝化修复效应研究

为研究天然黏土联合磷肥对农田土壤镉铅污染的原位钝化修复效应,在天津市某地开展了田间示范实验,以油麦菜、油菜和萝卜为模式作物,以海泡石、膨润土和磷肥等作为钝化修复材料,研究其对蔬菜可食部位生物量、镉铅含量和土壤中镉铅形态分布的影响,考察其对土壤镉铅污染的原位钝化修复效果.结果表明:磷肥、海泡石/磷肥复配、膨润土/磷肥复配...