脉冲电晕等离子法烟气脱硫脱硝的研究

本文探讨了脉冲电晕等离子法脱硫脱硝的基本原理，较系统地研究了影响脉冲电晕等离子烟气脱硫脱硝的主要因素，进行了加ＮＨ３脱硝的探索试验。实验表明：该法能有效地去除烟气中的ＳＯ２，但脱硝效果不明显，加ＮＨ３后可大量提高脱硝的效率；湿度对脱硫影响较大，湿度越高，脱硫效率也越高，当相对湿度达８０％时，脱硫率基本达到最大，而湿度对脱硝的影响不如脱硫明显；脉冲电压越高，功率越大，脱硫脱硝效率越高；增加放电极长度     

植物铜耐性机理的研究进展

主要从植物根细胞壁积累固定、细胞膜对铜的吸收控制、金属配体的螯合作用、铜在系统液泡的分隔机制及胁迫蛋白的合成5个方面,分别阐述植物对铜分子的耐性机制的研究进展,全面了解了铜在植物中的亚细胞分布、铜在植物根系到地上部分运输过程的转运机制以及植物在铜胁迫下的抗性反应等。并在此基础上提出了存在的问题以及今后研究的重点。     

双介质阻挡放电法再生吸附五氯酚的活性炭

采用双介质阻挡放电等离子体反应器对吸附了五氯酚的活性炭进行放电再生处理,考察了放电电压、放电时间、氧气流量和活性炭再生次数对再生活性炭的五氯酚去除率的影响.实验结果表明,活性炭再生的最佳条件为:放电电压23 kV,放电时间1.5h,氧气流量2.0 L/min.随活性炭再生次数增加,再生活性炭的五氯酚去除率和活性炭再生率...     

低温等离子体处理废液技术

低温等离子体技术包括热等离子体技术和冷等离子体技术。该技术处理废液具有范围广，快速，高交，无二次污染等优点，尤其对难降解有毒废液的处理，其先进性和优越性更为突出，被认为是21世纪环境污染物处理领域中最有发展前途的新技术之一。综述了低温等离子体处理废液技术的研究和应用进展，重点分析了冷等离子体技术处理难降解有机废液的作用机理，探讨了两种技术现存的主要问题，并指出了今后需要研究的方向。     

水介质中催化剂Raney Ni催化2-氯酚加氢脱氯

选择水作为反应介质,以氢气为氢源,研究了Raney Ni催化下、水溶液中2-氯酚的加氢脱氯,调查了溶剂、碱助剂和碱金属或碱土金属氯化物对加氢脱氯反应的影响.发现在水体系中,2-氯酚更容易被加氢脱氯,水作为反应介质时显著改善了加氢脱氯的反应环境,消除了无机氯化物在催化剂表面的吸附和累积,使催化剂保持了高活性.     

SO42-改性TiO2催化降解茜素红水溶液

基于SO42-对TiO2超强酸化改性制备了SO42-/TiO2催化剂,以茜素红为目标物试验研究了该催化剂的催化降解性能,并考察了降解条件等因素对脱色率的影响.结果表明,SO42-/TiO2具有较强催化降解性能及一定的光催化活性,降解过程中SO42-流失是催化剂失活的主要原因.在pH=7,催化剂加入量为2.5g/L,起始浓度为140mg/L,太阳光等优化工艺条件下降解效果最好,脱色率达到92%.     

低温等离子体氧化甲烷的实验研究

采用电容耦合等离子体对干空气中的甲烷进行氧化实验,对甲烷的分解效率、反应产物进行了分析。并且和放置催化剂时进行对比,结果表明放置催化剂后,甲烷的分解效率明显提高,反应产物中CO2 的选择性增加。甲烷的最终氧化产物都为CO、CO2 和H2 O。     

Synergistic removal of nitrogen monoxide using non-thermal plasma and catalyst simultaneously

An experimental system of De-NO with plasma-catalyst（Cu zeolite） was established to investigate the differences between De- NO with plasma-catalyst and De-NO only with plasma, to provide the instruction for selecting appropriate catalyst and operating condition, The characteristics of De-NO with plasma and De-NO with plasma-catalyst were investigated comparatively by experiments. The experimental results show that De-NO with plasma-catalyst has high NO removal rate; Cu zeolite is an effective catalyst which can promote NO removal rate in plasma remarkably; De-NO with plasma-catalyst should be operated at low temperature and the temperature has opposite effects on the function of catalvst and plasma; water vapor and O2 can increase the NO removal rate.     

Enhanced activation of peroxydisulfate by strontium modified BiFeO3perovskite for ciprofloxacin degradation

A series of Sr-doped BiFeO₃ perovskites (Bi_1-xSr_xFeO₃, BSFO) fabricated via sol-gel method was applied as peroxydisulfate (PDS) activator for ciprofloxacin (CIP) degradation. Various technologies were used to characterize the morphology and physicochemical features of prepared BSFO samples and the results indicated that Sr was successfully inserted into the perovskites lattice. The catalytic performance of BiFeO₃ was significantly boosted by strontium doping. Specifically, Bi_0.9Sr_0.1FeO₃ (0.1BSFO) exhibited the highest catalytic performance for PDS activation to remove CIP, where 95% of CIP (10 mg/L) could be degraded with the addition of 1 g/L 0.1BSFO and 1 mmol/L PDS within 60 min. Moreover, 0.1BSFO displayed high reusability and stability with lower metal leaching. Weak acidic condition was preferred to neutral and alkaline conditions in 0.1BSFO/PDS system. The boosted catalytic performance can be interpreted as the lower oxidation state of Fe and the existence of affluent oxygen vacancies generated by Sr doping, that induced the formation of singlet oxygen (¹O₂) which was confirmed as the dominant reactive species by radical scavenging studies and electron spin resonance (ESR) tests. The catalytic oxidation mechanism related to major ¹O₂ and minor free radicals was proposed. Current study opens a new avenue to develop effective A-site modified perovskite and expands their application for PDS activation in wastewater remediation.     

Fe3O4/FeS2活化H2O2降解典型苯胂酸类污染物

利用水热法成功制备了Fe₃O₄/FeS₂催化剂,并将其用于构建非均相芬顿体系降解典型的苯胂酸类污染物（洛克沙胂,ROX）.XRD、SEM、XPS和磁学测量系统（VSM）等表征结果表明,Fe₃O₄/FeS₂呈明显的颗粒状且具有良好的磁性.降解实验结果显示,在最优条件下（初始pH值为4.5、ROX起始浓度为20mg/L、Fe₃O₄/FeS₂投加量为0.15g/L和H₂O₂浓度为0.034g/L,Fe₃O₄/FeS₂介导的非均相芬顿体系可以超快速降解ROX,1min后的降解效率达到96.74%,明显优于单独的Fe₃O₄或FeS₂体系.此外,Fe₃O₄/FeS₂可以通过磁铁进行快速回收利用,同时也具有良好的重复利用性能,使用3次后,ROX的降解效率仍超过80%.机理分析表明,Fe₃O₄/FeS₂能够快速地催化H₂O₂产生具有强氧化性的羟基自由基（·OH）.在·OH的作-用下,ROX分子结构中C-As、C-N和C-C等化学键发生断裂,发生脱砷、脱硝和开环等反应,进而生成一系列的有机产物（如酚类、醌类、小分子有机酸等）和无机产物（As （V）和NO₃^-）.之后,无机砷能够被吸附在催化剂表面,而有机产物则进一步被矿化.