Preliminary studies on potential remediation of acid mine drainage‐impacted soils by amendment with drinking‐water treatment residuals

Mining operations result in a wide range of environmental impacts: acid mine drainage (AMD) and acid sulfate soils being among the most common. Due to their acidic pH and high soluble metal concentrations, both AMD and acid sulfate soils can severely damage the local ecosystems. Proper post‐mining management practices are necessary to control AMD‐related environmental issues. Current AMD‐impacted soil treatment technologies are rather expensive and typically not environmentally sustainable. We conducted a 60‐day bench‐scale study to evaluate the potential of a cost‐effective and environment‐friendly technology in treating AMD‐impacted soils. The metal binding and acid‐neutralizing capacity of an industrial by‐product, drinking water treatment residuals (WTRs) were used for AMD remediation. Two types of locally generated WTRs, an aluminum‐based WTR (Al‐WTR) and a lime‐based WTR (Ca‐WTR) were used. Highly acidic AMD‐impacted soil containing very high concentrations of metals and metalloids, such as iron, nickel, and arsenic, was collected from the Tab‐Simco coal mine in Carbondale, Illinois. Soil amendment using a 1:1 Al‐ and Ca‐WTR mix, applied at 5 and 10 percent rates significantly lowered the soluble and exchangeable fractions of metals in the AMD‐impacted soil, thus lowering potential metal toxicity. Soil pH increased from an extremely acidic 2.69 to a near‐neutral 6.86 standard units over the 60‐day study period. Results from this preliminary study suggest the possibility of a successful scale‐up of this innovative, cost‐effective, and environmentally sustainable technology for remediating AMD‐impacted acid sulfate soils.     

硫酸盐还原菌污泥固定化特性

采用玉米芯为碳源,聚乙烯醇(PVA)为包埋载体,饱和硼酸(H3BO3)为交联剂,研究了硫酸盐还原菌污泥(SRBS)、铁屑、麦饭石共固处理合成煤矿酸性废水的最优配比与机理,并分析了固定化过程中小球稳定性及活性的变化规律。实验结果表明,SRBS投加量是影响处理效果的最显著因子,当投加30%SRBS、2%铁屑、3%麦饭石时SO2-4、Mn2+去除率分别为94.13%和84.39%,溶液p H为7.03,未检测出Fe2+;随着交联时间的延长,小球膨胀率及SO2-4还原率分别呈线性与指数下降,从保持小球稳定性与活性角度考虑,可将交联时间设定为4~8 h;该法可为市政污泥的处置以及生物法处理煤矿酸性废水的工程应用提供技术参考。     

Mitigating Impact of Devils Lake Flooding on the Sheyenne River Sulfate Concentration

Devils Lake is a terminal lake located in northeast North Dakota. Because of its glacial origin and accumulated salts from evaporation, the lake has a high concentration of sulfate compared to the surrounding water bodies. From 1993 to 2011, Devils Lake water levels rose by ~10 m, which flooded surrounding communities and increased the chance of an overspill to the Sheyenne River. To control the flooding, the State of North Dakota constructed two outlets to pump the lake water to the river. However, the pumped water has raised concerns about of water quality degradation and potential flooding risk of the Sheyenne River. To investigate these perceived impacts, a Soil and Water Assessment Tool (SWAT) model was developed for the Sheyenne River and it was linked to a coupled SWAT and CE‐QUAL‐W2 model that was developed for Devils Lake in a previous study. While the current outlet schedule has attempted to maintain the total river discharge within the confines of a two‐year flood (36 m³/s), our simulation from 2012 to 2018 revealed that the diversion increased the Sheyenne River sulfate concentration from an average of 125 to >750 mg/L. Furthermore, a conceptual optimization model was developed with a goal of better preserving the water quality of the Sheyenne River while effectively mitigating the flooding of Devils Lake. The optimal solution provides a “win–win” outlet management that maintains the efficiency of the outlets while reducing the Sheyenne River sulfate concentration to ≤600 mg/L.     

过一硫酸盐的活化及其降解水中有机污染物机理的研究进展

基于活化过一硫酸盐（PMS）产生SO₄^-·的新型高级氧化技术,在芬顿和类芬顿催化降解水中有机污染物的研究中占有重要地位。本文从活化PMS方法的特点和用途出发,对目前活化PMS的主要方法进行了论述,并对活化PMS降解水中有机污染物的机理进行了探讨,最后对该领域研究中存在的问题进行了分析。指出,开发高效的协同活化PMS的方法将成为该领域研究的必然趋势。     

微生物电解系统生物阴极的硫酸盐还原特性研究

针对传统硫酸盐生物还原方法中供氢体系能耗大和氢气利用率低的特点,构建双极室微生物电解系统(microbial electrolysis system,MES),研究了微生物利用阴极作为电子供体去除废水中硫酸盐及电子利用的特性.外加电压为0.8 V时,MES生物阴极在36 h内SO2-4平均去除量为109.8 mg·L-1,平均还原速率可达73.2 mg·(L·d)-1.运行时MES的最高电流密度为50~60 A·m-3,电子回收率为(43.3±10.7)%,约90%的电子被用于还原SO2-4.微生物利用MES阴极产生的H2作为电子供体还原SO2-4,主要还原产物为溶解态的S2-和气态的H2S,还原过程主要发生在前12 h.对MES施加不同外加电压的实验显示,外加电压为0.8 V时的SO2-4去除率和电荷量都比0.4 V时高;但0.4 V情形下MES的电子回收率可达到70%,且周期结束时阴极H2低于检出限,推测微生物可以直接利用阴极的电子从而提高了能量效率.实验结果最终表明,微生物可利用MES的阴极进行代谢去除废水中的SO2-4,阳极微生物产生电子降低了系统能耗,这为含硫酸盐废水的高效低耗处理提供了新的研究思路.     

氟化铵制备氟化钙最优条件研究

试验采用氟化铵与石灰石粉、石灰乳反应制取氟化钙,研究了反应温度、物料浓度、物料过量系数等各主要参数变化对氟化钙结晶、过滤速度、氟收率及其含量的影响,摸索出最优反应条件。     

都匀毛尖茶土壤中总磷含量的调查研究

目的:调查都匀毛尖茶土壤中总磷的含量;方法:以贵州省都匀市毛尖茶产地--螺丝壳山的土壤为研究对象,采用酸法消解,用钼酸铵分光光度法于700 nm波长处测定土壤中总磷含量;结果:都匀螺丝壳山中土壤中总磷含量在177.58 mg·kg-1~353.92 mg·kg-1之间;结论:都匀毛尖茶土壤中的总磷含量在全国基本水平范围以内,总磷含量与土壤的类型、土壤所处海拔高度无明显关系。     

冻融作用对酸化土壤中NH_4~+吸附特性的影响研究

以吉林农业大学长期定位试验田土壤为研究对象,采用室内模拟冻融环境和振荡平衡的方法,探讨冻融作用对NH+4在酸化土壤中吸附特性的影响。结果表明,随着冻融周期的增加,酸化土壤对NH+4的吸附量逐渐减小;冻结时间对酸化土壤吸附NH+4的影响不明显;随着冻前含水量的增加,酸化土壤对NH+4的吸附量逐渐减小,对NH+4的吸附量由大到小排列为:15%25%35%。酸化土壤对NH+4的吸附过程能很好地利用Langmuir方程拟合,冻融作用促进酸化土壤中NH+4的释放,增加了NH+4流失风险。     

硫酸铵和尿素对废物焚烧过程中多种途径生成氯苯类的抑制作用

氯苯类(CBz)是废弃物焚烧等过程中产生二英的前驱物,也被认为是实现二英在线检测的良好指示物,同时五氯苯(PeCBz)和六氯苯(HxCBz)也是持久性有机污染物(POPs).但氯苯在废物焚烧过程中的排放和控制尚没有受到足够重视,为此开展了模拟焚烧过程中硫酸铵和尿素对3种氯苯合成途径的抑制作用研究,包括飞灰合成,1,2-二氯代苯(1,2-DiCBz)转化高氯代苯等过程.结果表明,硫酸铵和尿素对氯苯的3种合成途径均有抑制作用,如1%尿素与废物混合焚烧对四氯苯、五氯苯和六氯苯的抑制效率分别达到了66.8%、57.4%和50.4%.比较硫酸铵和尿素对3种过程的抑制作用,认为尿素对氯苯具有更稳定的抑制能力.     

有效磷含量对硝酸铵溶液热安全性的影响

为了了解硝酸磷肥生产过程中,硝酸铵溶液中加入磷酸一铵的安全性,通过自制实验装置,研究了有效磷含量对质量分数为85%的硝酸铵溶液热分解的影响。结果表明,质量分数为85%的硝酸铵和磷酸一铵混合溶液的临界爆炸温度高于纯质量分数为85%的硝酸铵溶液,稳定性更好;磷酸一铵抑制硝酸铵的热分解,随着有效磷含量的增加,硝酸铵混合溶液临界爆炸温度升高;升温速率对硝酸铵混合溶液的临界爆炸温度影响很大,随着升温速率由2℃/min升高到3℃/min,质量分数为85%的硝酸铵混合溶液的临界爆炸温度升高,不易发生爆炸,安全性更好。研究结果对硝酸磷肥的生产安全有一定的指导意义。