自然型氨基酸及其钾盐的 CO2吸收和再生特性

在CO2吸收过程中,选择具有不挥发和不发生氧化降解特性的氨基酸盐吸收剂有助于降低吸收剂损失和减轻环境污染风险,故本研究以CO2吸收速率和再生速率为指标,对L-精氨酸和精氨酸钾（PA）吸收剂的CO2吸收性能和常压下热再生性能进行了实验分析,并研究了吸收剂质量分数、反应温度及吸收-再生循环次数对CO2吸收特性的影响,同时还与乙醇胺（MEA）、二乙醇胺（DEA）和三乙醇胺（TEA）进行了对比分析.结果表明,在实验的质量分数范围内,PA具有最高的CO2吸收速率和吸收能力,分别为24.5×10-3mol.（L.min）-1和1.99 mol.mol-1,比相同质量分数的MEA高2.1%和290.2%.温度影响结果表明,40℃时PA和MEA的CO2吸收速率均高于其他实验温度.相同再生条件下,PA的贫液CO2负荷要略高于MEA,但PA的再生程度可达72.8%,比MEA高19%.同时,3次＂吸收-再生＂循环之后,10%PA的CO2吸收能力仍可保持在1.03mol.mol-1,比10%MEA高255.2%.实验结果也表明,L-精氨酸具有较强的CO2吸收能力,其CO2吸收速率与同质量分数的DEA可比.     

Identification of key factors governing chemistry in groundwater near the water course recharged by reclaimed water at Miyun County, Northern China

Reclaimed water was successfully used to recover the dry Chaobai River in Northern China, but groundwater may be polluted. To ensure groundwater protection, it is therefore critical to identify the governing factors of groundwater chemistry. Samples of reclaimed water, river and groundwater were collected monthly at Chaobai River from January to September in 2010. Fifteen water parameters were analyzed. Two kinds of reclaimed water were different in type (Na-Ca-Mg-Cl-HCO3 or Na-Ca-Cl-HCO3 ) and concentration of nitrogen. The ionic concentration and type in river were similar to reclaimed water. Some shallow wells near the river bed had the same type (Na-Ca-Mg-Cl-HCO3 ) and high concentration as reclaimed water, but others were consistent with the deep wells (Ca-Mg-HCO3 ). Using cluster analysis, the 9 months were divided into two periods (dry and wet seasons), and all samples were grouped into several spatial clusters, indicating different controlling mechanisms. Principal component analysis and conventional ionic plots showed that calcium, magnesium and bicarbonate were controlled by water-rock interaction in all deep and some shallow wells. This included the dissolution of calcite and carbonate weathering. Sodium, potassium, chloride and sulfate in river and some shallow wells recharged by river were governed by evaporation crystallization and mixing of reclaimed water. But groundwater chemistry was not controlled by precipitation. During the infiltration of reclaimed water, cation exchange took place between (sodium, potassium) and (calcium, magnesium). Nitrification and denitrification both happened in most shallow groundwater, but only denitrification in deep groundwater.     

区域大气环境容量资源优化利用的博弈分析

大气环境容量是一种公共资源,合理利用和保护大气环境容量资源是大气环境改善的有效途径.从区域内各城市间的博弈行为出发,利用个人决策模型、整体决策模型、关系模型对区域内大气容量资源进行分析,揭示大气容量资源被过度使用的现象,针对城市监管不力、企业排污严重引起大气污染问题而提出帕累托改进模型,指出大气环境保护需要合作机制,联防联控.     

模型模拟在城市SO2环境容量测算中的应用研究

以许昌市污染源普查数据为基础,通过现状排放、环境质量控制目标与预测环境质量、污染物削减和浓度贡献分析,核定得到了准确可靠的许昌市二氧化硫环境容量;研究建立的从宏观理想容量到实际容量的多源模型体系,能较好地应用于二氧化硫环境容量研究;A—P值法、AERMOD模型均能较好地模拟污染源与环境空气质量的响应关系,且二者具有较好的一致性,可作为可靠的多源模型广泛应用于中小城市的二氧化硫环境容量核定研究及环境规划管理。     

能源承载力预测分析方法的研究与应用研究

能源需求和人口、经济密切相关。能源需求分析是在一定的人口和经济增长假设下进行的。从投入产出角度看,能源需求的高低取决于终端需求与满足终端需求的中间过程。经济结构的变化,经济增长模式的选择,技术进步,优质能源的可获得性,环境保护要求等因素会对终端需求和中间过程产生影响。由于资源对国家和地区的重要性,资源承载力的研究显得尤为重要。因此有必要对一个区域的能源需求量作出预测和分析,提高区域发展和管理的科学性,从而实现区域的可持续发展。     

昆明市环境应急监测能力建设现状及对策建议

结合昆明市环境应急监测能力建设的现状,着重分析存在的主要问题,提出了相应的对策建议。     

新型磁性聚谷氨酸吸附剂对水中Pb2+的吸附去除

德岛大学安澤幹人首次利用γ-PGA在Fe3O4磁性纳米颗粒上进行涂层,制得了γ-聚谷氨酸-Fe3O4磁性纳米颗粒（PG-M）.本实验利用透射电镜以及扫描电镜对PG-M吸附剂的形貌进行了分析,发现PG-M与未涂层的Fe3 O4具有相似的形状以及大小,均为不规则的层状结构,且晶粒直径在120～320 nm之间;实验中针对性地对水溶液中Pb2＋进行了吸附探讨.在振荡实验中,通过主要参数的变化（pH值、吸附时间、竞争离子浓度、腐殖酸浓度）,得到如下结果：吸附最佳pH值为7.0;吸附量随着吸附时间的延长而增长,吸附平衡时间为45 min;Na＋对PG-M去除Pb2＋没有很强的干扰性,而Ca2＋则显示出一定的干扰作用;腐殖酸对吸附效果的影响是复杂的,表现为先增强吸附效果,随后降低吸附效果;最佳条件时Pb2＋的最大吸附量为93.3 mg/g.PG-M对Pb2＋的吸附均能较好地符合Freundlich和Langmuir等温吸附模型,其中Langmuir方程能更好地描述PG-M的吸附特征,说明PG-M在水溶液中对金属离子的吸附为单分子层吸附.PG-M吸附符合准二级动力学模型（r2〉0.99）.不同浓度的HCl和HNO3溶液的再生实验发现,0.1 mol/L的HCl溶液作为吸附再生液,可取得较好的再生效果.表明PG-M是可再生的,具有较好的经济性和可持续性.     

辽河保护区治理与保护能力建设研究

辽河保护区治理与保护能力的建设,通过界碑、围栏、标示牌、宣传牌等设施建设,重点区域的水质、生态监测站点建设,保护区综合管理平台建设,应急保障体系建设,形成保护区完善的综合监控网络体系,全面提高保护区基础设施与监控能力。同时,应使全民参与对＂母亲河＂的保护。     

沸石强化生化装置脱氮功能的效果及机理初探

针对石化工业废水开展沸石强化脱氮处理试验研究,通过比较沸石浓度25mg/L与空白,以及沸石浓度25 mg/L与50mg/L两阶段脱氮效果,探讨沸石促进脱氮功能的机理,结果表明,曝气池中投加沸石可明显提高氨氮和总氮的去除率,硝化细菌总数和硝化功能也得到增强。与空白对照组相比, 沸石浓度25mg/L的试验组运行稳定后,氨氮去除率提高约10%~13%,总氮去除率约提高13%,出水中NO3--N含量约提高100%,氨氮与总氮之比下降6%,内源硝化耗氧呼吸速率可提高138%,硝化细菌总数是空白对照组2.2folds。沸石浓度提高到50mg/L后,试验组的脱氮效果略有增加,但效果不明显。通过对试验结果的关联分析,认为沸石提高系统脱氮能力的原因一方面是因为沸石对NH4+及硝态氮的交换吸附,另一方面NH4+离子富集于沸石表面及内部、沸石颗粒独特的好氧-缺氧微环境,以及沸石离解出CO32- 或HCO3-增加碱度等条件,促进了硝化细菌和反硝化细菌的生长,从而提高了系统脱氮能力。     

Assessing field vulnerability to phosphorus loss in Beijing agricultural area using Revised Field Phosphorus Ranking Scheme

Guanting Reservoir,one of the drinking water supply sources of Beijing,suffers from water eutrophication.It is mainly supplied by Guishui River.Thus,to investigate the reasons of phosphorus(P)loss and improve the P management strategies in Guishui River watershed are important for the safety of drinking water in this region.In this study,a Revised Field P Ranking Scheme(PRS)was developed to reflect the field vulnerability of P loss at the field scale based on the Field PRS.In this new scheme,six factors are included, and each one was assigned a relative weight and a determination method.The affecting factors were classified into transport factors and source factors,and,the standards of environmental quality on surface water and soil erosion classification and degradation of the China were used in this scheme.By the new scheme,thirty-four fields in the Guishui River were categorized as"low","medium"or"high"potential for P loss into the runoff.The results showed that the P loss risks of orchard and vegetable fields were higher than that of corn and soybean fields.The source factors were the main factors to affect P loss from the study area.In the study area,controlling P input and improving P usage efficiency are critical to decrease P loss.Based on the results,it was suggested that more attention should be paid on the fields of vegetable and orchard since they have extremely high usage rate of P and high soil test of E Compared with P surplus by field measurements,the Revised Field PRS was more suitable for reflecting the characteristics of fields,and had higher potential capacity to identify critical source areas of P loss than PRS.