氯代苯类有机物生物降解性能的研究

采用连续、完全混合活性污泥法,对重点污染物中六种氯代苯类有机物(氯苯、1,2-二氯苯、1,3-二氯苯、1,4-二氯苯、1,2,4-三氯苯、六氯苯)的生物降解性能进行了研究。试验表明,除六氯苯外,其它五种氯代苯均能被驯化后的微生物所降解。随着苯环上氯取代基的增加,氯代苯的生物降解速率降低。在2B天的连续试验中,六氯苯基本上不能被微生物所降解。     

MWNTs/TiO2对典型氯苯类化合物的光催化降解研究

研究复合光催化剂MWNTs/TiO2对典型氯苯类有机化合物光催化降解动力学及主要光降解路径.结果表明,同一初始浓度和相同光催化降解实验条件下,60min时典型氯苯类有机化合物的光降解率均达到90%以上.其中六氯苯和五氯苯的光催化降解速率常数分别为0.0664h-1和0.0670h-1,其大小明显高于其它氯苯类化合物.1,二氯苯的光催化降解反应速率常数仅为0.0430h4--1,在典型氯苯类化合物中最小.三氯苯的3种同分异构体——1,3-三氯苯、24-三氯苯和1,5-三氯苯的光催化降解速率常数分别为0.0547h2,1,,3,-1、0445h0.-1和0.0439h-1.六氯苯的主要光催化降解路径为:HCB→PeCB→1,2,3,5-TeCB→1,2,4-TCB→1,4-DCB.     

固体吸附热脱附-气相色谱质谱法测定大气中34种挥发性有机物

建立了固体吸附热脱附-气相色谱质谱法测定大气中的1,1,2-三氯-1,2,2-三氟乙烷、1,1-二氯乙烯、氯丙烯、二氯甲烷、1,1-二氯乙烷、顺式-1,2-二氯乙烯、三氯甲烷、1,1,1-三氯乙烷、四氯化碳、苯、1,2-二氯乙烷、三氯乙烯、1,2-二氯丙烷、反式-1,3-二氯丙烯、甲苯、顺式-1,3-二氯丙烯、1,1,2-三氯乙烷、四氯乙烯、1,2-二溴乙烷、氯苯、乙苯、1,1,1,2-四氯乙烷、间,对-二甲苯、邻-二甲苯、苯乙烯、4-乙基甲苯、1,3,5-三甲基苯、1,2,4-三甲基苯、1,3-二氯苯、1,4-二氯苯、苄基氯、1,2-二氯苯、1,2,4-三氯苯、六氯丁二烯的分析方法,与采样罐法相比,该法更为简单快捷。在2.5~50μg/m3内线性在0.993~0.999,加标回收率在85.8%~119.2%,且准确度高,相对标准偏差在2.1%~6.9%,方法检出限在0.03~2.52μg/m3。     

腐殖酸强化六氯苯厌氧降解规律及其中间产物

为探索厌氧条件下HA(腐殖酸)对HCB(六氯苯)降解的影响,通过构建ρ(HA)为0(HA₀)、120(HA₁₂₀)及200(HA₂₀₀)mg/L厌氧发酵体系,利用气相色谱-电子捕获检测器(GC-ECD)对ρ(HCB)及中间产物进行测定. 结果表明:发酵系统运行72 h后,HA₀、HA₁₂₀、HA₂₀₀处理中HCB降解率分别为13.0％、16.5％和17.4％,表明HA可以促进HCB的降解,并且随ρ(HA)的增加,降解效果越好,但降解效率增幅降低. 对HCB脱氯中间产物的分析发现,PeCB(五氯苯)、TeCB(四氯苯)、TCB(三氯苯)和DCB(二氯苯)均有检出;在发酵的前12 h,ρ(DCB)快速增加,发酵72 h后HA₀、HA₁₂₀、HA₂₀₀处理中ρ(DCB)分别为50.6、51.0和57.6 μg/L,明显高于其他中间产物,表明DCB是HCB脱氯的限速中间体;对DCB进行同分异构体分析表明,DCB的同分异构体有1,2-DCB、1,3-DCB和1,4-DCB三种,发酵结束后HA₀、HA₁₂₀和HA₂₀₀处理中ρ(1,4-DCB)最高,分别为22.0、17.2和18.7 μg/L,1,4-DCB为HCB降解的主要中间产物. 研究显示,通过调控厌氧发酵体系内HA的含量可达到强化HCB脱氯的目的.      

金属催化还原技术对p-二氯苯的脱氯

研究了Pd/Fe双金属体系对p-二氯苯(p-DCB)的快速催化还原脱氯处理. 结果表明, 在Pd的催化作用下,零价Fe对p-DCB具有较好的还原脱氯效率. 当Pd/Fe双金属的钯化率为0.02%,催化还原剂的用量为4g/75mL,反应90min p-DCB脱氯率达到90%以上;p-DCB的脱氯效率与溶液初始pH值、反应温度、钯化率、Pd/Fe投加量等因素有关;p-DCB在催化还原脱氯过程中先生成氯苯,而后继续脱氯生成苯.     

驯化污泥厌氧还原脱氯促进2,4,6-三氯酚矿化及胞外呼吸脱氯途径

厌氧条件下,以乳酸钠为电子供体,2,4,6-三氯酚为电子受体对活性污泥进行驯化,考察了驯化污泥厌氧脱氯的代谢特性.结果发现,污泥可对2,4,6-三氯酚进行高效脱氯,乳酸钠、2,4,6-三氯酚初始浓度为20 mmol·L-1、40~80μmol·L-1时,9~24 h内可实现2,4,6-三氯酚100%初始性降解.中间产物有2,4-二氯酚,但检出浓度较低(4.22μmol·L-1),4-氯酚和苯酚为主要产物.驯化污泥以脱邻位氯(2,4,6-三氯酚,2,4-二氯酚)降解菌为优势种群,对4-氯酚和苯酚的进一步转化有限.厌氧代谢残留物经好氧污泥处理后,4-氯酚(初始浓度33μmol·L-1)2 h实现100%去除.驯化污泥可快速将Fe(Ⅲ)还原为Fe(Ⅱ),并具有较强的腐殖质(AQDS)还原能力,说明驯化污泥中富集了异化铁还原菌.电子介体[Fe(Ⅲ)和AQDS]明显地加速了脱氯速率,在电子介体的介导作用下,污泥可同步进行胞外呼吸脱氯.     

1,3-二氯苯降解细菌Bacillus cereus PF-11的遗传选育及其降解特性研究

以焦化厂废水中分离得到的一些苯降解细菌为出发菌 ,通过遗传突变方法获得了一株高效降解 1,3 二氯苯的突变株PF 11.在合适条件下突变株PF 11培养液对 1,3 二氯苯的降解速率可达 31mg (L·d) ,并伴随着有效的氯离子释放 .经初步鉴定 ,突变株PF 11为以前未见报导的革兰氏阳性Bacilluscercus菌 .菌株PF 11的底物专一性较低 ,对单氯苯和 1,2 二氯苯均有降解作用 ,降解能力为单氯苯 >1,3 二氯苯 >1,2 二氯苯 .初步推测最初反应步骤是双加氧酶催化的分子氧攻击苯环形成二氯邻苯二酚     

氯苯类化合物的生物降解

经过2个月的驯化,从某染料厂和某毛纺厂活性污泥中分离出能够生长于1,4-二氯苯、1,2,4-三氯苯和六氯苯的4种微生物.通过测定该混合菌降解氯苯类化合物过程中的累积好氧量、微生物生长曲线及降解产物Cl^-的释放,证明在好氧条件下该混合菌能够以1,4二氯苯和1,2,4-三氯苯为唯一碳源和能源,降解产物Cl^-浓度的变化与微生物生长周期有关.通过好氧振荡瓶培养法测得3种氯苯的生物降解顺序为:1,4-二氯苯[356.7μg/(L·d)]>1,2,4-三氯苯[110.4μg/(L·d)]>六氯苯[～6μg/(L·d)],说明氯取代数越多,氯苯类化合物越难被好氧降解.     

不同pH条件下三氯乙烯及其脱氯产物对苯或甲苯厌氧生物降解的影响

将零价铁渗透反应格栅和生物降解格栅联用,先利用氯代烃易还原脱氯的性质通过零价铁渗透反应格栅去除氯代烃,后利用BTEX易生物降解的性质通过生物降解格栅去除BTEX,可以有效去除地下水中由氯代烃和BTEX这两种性质迥异的污染物形成的混合污染羽.但在联合格栅技术中,零价铁渗透反应格栅后的强碱性环境(pH9)、氯代烃脱氯还原中间产物(cis-1,2-DCE)的积累和可能出现的TCE穿透均可对生物降解格栅中BTEX的生物降解产生影响.针对上述问题,本文研究了不同pH条件下TCE和cis-1,2-DCE对苯或甲苯厌氧生物降解的影响.结果发现,碱性pH条件有利于苯或甲苯的生物降解,但不同pH条件下TCE或cis-1,2-DCE的加入对苯或甲苯的生物降解均产生抑制(除pH=7.9,cis-1,2-DCE=100μg·L-1时的甲苯),且TCE对苯和甲苯生物降解的抑制要明显强于cis-1,2-DCE;不同pH条件下,TCE 100和500μg·L-1对苯生物降解的抑制作用没有明显差异,但对甲苯生物降解的抑制却随着TCE浓度的增加而增加;pH=7.9时,cis-1,2-DCE的加入有利于甲苯的生物降解,之后随着pH的增加又转变为抑制.另外,在苯或甲苯厌氧生物降解过程中,可能存在cis-1,2-DCE与苯或甲苯的共代谢生物降解,且甲苯更有利于cis-1,2-DCE的共代谢降解.     

Catalytic dechlorination of o-cllorophenol by nanoscale Pd/Fe

Transformation of chlorophenols by nanoscale bimetallic particles represents one of the latest innovative technologies for environmental remediation. Nanoscale Pd/Fe bimetallic particles were synthesized in the laboratory for treatment of o-chlorophenol. Most of the nanoscale particles are in the size range of 20-100 nm. BET specific surface area of the nanoscale Pd/Fe particles is 12.4 m2/g. In comparison, a commercially available Fe powder( ＜100 mesh) has a specific surface area of just 0.49 m2/g. Batch experiments demonstrated that the nanoscale Pd/Fe bimetallic particles can effectively dechlorinate o-chlorophenol. Dechlorination efficiency is affected by the mass fraction of Pd in the bimetal, nanoscale Pd/Fe mass concentration and mixing intensity.     

Catalytic dechlorination of o-chlorophenol by nanoscale Pd/Fe

IntroductionTheuseofzerovalentironforthetreatmentofchlorinatedorganiccompounds (COCs )inwaterandgroundwaterhasbeenthefocusofmuchrecentresearch .Thestudieswereconcernedwithcompoundssuchascarbontetrachloride(Bradley ,1995 ) ,trichloroethene(Orth ,1996 ;Chen ,2 0 0 1)andpesticidesandrelatedcompounds(Sayles,1997;Monson ,1998;Eykholt,2 0 0 1;Dombek ,2 0 0 1) .Whenironisincontactwithalessreductivemetal,themetalcouplecanformgalvaniccells.ThishasledtothediscoveryofPd Febimetalliccomplexinwhichpal…     

Catalytic dechlorinafion of o-chlorophenol by nanoscale Pd／Fe

Transformation of chlorophenols by nanoscale bimetallic particles represents one of the latest innovative technologies for environmental remediation. Nanoscale Pd/Fe bimetallic particles were synthesized in the laboratory for treatment of o-chlorophenol. Most of the nanoscale particles are in the size range of 20-100 nm. BET specific surface area of the nanoscale Pd/Fe particles is 12.4 m2/g. In comparison, a commercially available Fe powder( < 100 mesh) has a specific surface area of just 0.49 m2/g. Batch experiments demonstrated that the nanoscale Pd/Fe bimetallic particles can effectively dechlorinate o-chlorophenol. Dechlorination efficiency is affected by the mass fraction of Pd in the bimetal, nanoscale Pd/Fe mass concentration and mixing intensity.     

Electroreductive dechlorination of chlorophenols with Pd catalyst supported on solid electrode

Electroreductive dechlorination of chlorophenols with Pd catalyst supported on solidelectrode was studied. As solid electrodes, carbon cloth (CC), carbon felt (CF) and titanium mesh were used, and palladium was plated on solid electrodes by either electrolytic or electroless method. On each electrode with Pd, chlorophenols were qualitatively dechlorinated to phenol, while they were entirely intact on electrodes without Pd. Moreover, neither base electrode nor plating method significantly affected the activity of Pd as far as it was sufficiently loaded on the electrode. Based on the results in the experiments using one electrode repeatedly, Pd catalyst proved to possess a satisfactory duarability under the present condition. It was suggested that the reactive species responsinble for the dechlorination of chlorophenols could be formed during preliminary electrolysis. Thus, (Pd)_x-H resulting from the adsorption of electrogenerated hydrogen on metallic Pd might be assumed most probable.     

Electroreductive dechlorination of chlorophenols with Pd catalyst supported on solid electrode

Electroreductive dechlorination of chlorophenols with Pd catalyst supported on solidelectrode was studied. As solid electrodes, carbon cloth (CC), carbon felt (CF) and titanium mesh were used, and palladium was plated on solid electrodes by either electrolytic or electroless method. On each electrode with Pd, chlorophenols were qualitatively dechlorinated to phenol, while they were entirely intact on electrodes without Pd. Moreover, neither base electrode nor plating method significantly affected the activity of Pd as far as it was sufficiently loaded on the electrode. Based on the results in the experiments using one electrode repeatedly, Pd catalyst proved to possess a satisfactory duarability under the present condition. It was suggested that the reactive species responsinble for the dechlorination of chlorophenols could be formed during preliminary electrolysis. Thus, (Pd)_x-H resulting from the adsorption of electrogenerated hydrogen on metallic Pd might be assumed most probable.     

泡沫镍/铁粉脱氯降解莠去津

在 Ni/Fe 二元金属粉末脱氯降解莠去津的基础上,为了减少镍的流失对环境产生的二次污染,采用泡沫镍/铁粉体系作为还原剂,研究其对莠去津的脱氯效率,并和铁粉、Ni/Fe 二元金属体系的催化特性进行了比较.结果表明,在相同的反应条件下(pH 2.0,莠去津初始浓度20.0mg/L),泡沫镍为 1.0g,铁粉添加量分别为 2.0,3.0,5.0g 时,反应 90min,脱氯效率分别增加 14.11%、15.97%、29.50%;泡沫镍+铁粉分别为0+5.0g、0.5g+5.0g、1.0g+5.0g、1.95g+5.0g 时,莠去津 90min 的脱氯效率分别为 52.76%、80.13%、82.26%、65.25%.但是与 Ni/Fe 二元金属相比,催化性能要低得多,这可能与泡沫镍/铁粉体系的比表面积下降有关.     

乳化纳米铁(EZVI)强化地下水氯代烃还原脱氯

对氯代烃污染地下水进行厌氧微生物还原脱氯时,存在微生物驯化时间长、pH值持续降低、有毒中间产物累积等限制修复效率的问题,为解决上述问题,本课题组制备了一种乳化油(EVO)包覆纳米零价铁(NZVI)的修复试剂,即乳化纳米铁(EZVI),其可以抑制NZVI钝化,增强反应速率并促进厌氧微生物脱氯反应.通过静态批实验探究了EZVI与三氯乙烯的反应动力学及EZVI对四氯乙烯(PCE)还原脱氯的中间代谢产物,并阐明了该过程机理.结果表明EZVI可以有效延缓NZVI钝化、提高反应活性,反应符合一级反应动力学,k_obs=0.182d^-1;EZVI还原PCE可以减少中间产物二氯乙烯的积累,10天内去除PCE达到97.2%,比EVO还原体系提高了68.9%;反应过程中pH值保持在6.5~7.5,ORP值在-50~10mV,提供了良好的还原环境,有效促进了厌氧微生物脱氯反应进行.     

含氯漂白废水在厌氧过程中脱氯机理的研究

厌氧法能有效地去除废水中的氯代有机物，通过GC－MS测试漂白废水厌氧处理过程中污染物组分的变化证实了厌氧过程中还原脱氯机制，而废水厌氧过程中产生的硫化物和pH值对厌氧过程中氯代有机物脱氯的影响，则证实厌氧过程中还存在亲核取代和碱性水解非生物脱氯机制。     

Catalytic dechlorination of chlorobenzene in water by Pd/Fe bimetallic system

IntroductionChlorinatedorganiccompoundshavebeenusedonalargescaleinthechemical,petrochemical,andelectronicindustries.Inrecentyears ,worldwideattentionhasbeengiventotheenvironmentalandhealthimpactofthemasaclassofcontaminants .Severalareknowntocauseozonedepletion ,whileothersproduceadverseeffectsonthehumancentralnervoussystemandhavebeenlinkedtodiseasessuchascancer.Almostallofthechlorinatedaromaticcompoundsaretoxicandthermallystable .Oncereleasedintoenvironment,theywillaccumulateinthesurroundings…     

Catalytic reductive dechlorination of p–chlorophenol in water using Ni/Fe nanoscale particles

Nanoscale bimetallic Ni/Fe particles were synthesized from the reaction of sodium borohydride （NaBH4） with reduction of Ni^2＋ and Fe^2＋ in aqueous solution. The obtained Ni/Fe particles were characterized by TEM （transmission electron microscope）, XRD （X-ray diffractometer）, and N2-BET. The dechlorination activity of the Ni/Fe was investigated using p-chlorophenol （p-CP） as a probe agent. Results demonstrated that the nanoscale Ni/Fe could effectively dechlorinate p-CP at relatively low metal to solution ratio of 0.4 g/L （Ni 5 wt%）. The target with initial concentration ofp-CP 0.625 mmol/L was dechlorinted completely in 60 rain under ambient temperature and pressure. Factors affecting dechlorination efficiency, including reaction temperature, pH, Ni loading percentage over Fe, and metal to solution ratio, were investigated. The possible mechanism of dechlorination ofp-CP was proposed and discussed. The pseudo-first- order reaction took place on the surface of the Ni/Fe bimetallic particles, and the activation energy of the dechlorination reaction was determined to be 21.2 kJ/mol at the temperature rang of 287-313 K.