Decomposition of hexachlorobenzene over Al_2O_3 supported metal oxidecatalysts

Decomposition of hexachlorobenzene(HCB)was investigated over several metal oxides(i.e.,MgO,CaO,BaO,La2O3,CeO2,MnO2, Fe2O3,and Co3O4)supported on Al2O3,which was achieved in closed system at a temperature of 300°C.Catalysts were prepared by incipient wetness impregnation with different metal oxides loading and impregnating solvents.The decomposition effciency of different catalysts for this reaction depends on the nature of the metal oxide used,and Al2O3 supported La2O3 was found to be the most active one.Pe...

Monitoring bioaccumulation and toxic effects of hexachlorobenzene using the polyurethane foam unit method in the microbial communities of the Fuhe River,Wuhan

Hexachlorobenzene （HCB） is a chlorinated aromatic hydrocarbon that was widely used for seed dressing in prevention of fungal growth on crops, and also as a component of fireworks, ammunition, and synthetic rubbers. Because of its resistance to degradation and mobility, HCB is widely distributed throughout the environment and is accumulated through food chains in different ecosystems. In this study, a preliminary investigation was carried out on the bioaccumulation and the toxic effects of HCB in the microbial （protozoan in particular） communities in the Fuhe River, Wuhan, a water body receiving industrial wastewaters containing HCB and other pollutants, using the standardized polyurethane foam units （PFU） method. Field samples were taken from eight stations established along the Fuhe River in January and August 2006. The concentration ratios of HCB in microbial communities and in water were 9.66-18.64, and the microbial communities accumulated 13.29-56.88 μg/L of HCB in January and 0.82-10.25 μg/L HCB in August. Correlation analysis showed a negative correlation between the HCB contents in the microbial assemblage, and the number of species and the diversity index of the protozoan communities. This study demonstrated the applicability of the PFU method in monitoring the effects of HCB on the level of microbial communities.

Hexachlorobenzene Episode in Turkey

During the period 1955-1959, approximately 4000 people in southeast Anatolia developed porphyria due to the ingestion of hexachlorobenzene (HCB), a fungicide added to wheat seedlings. These HCB exposures subsequently led to the development of bullae on sun-exposed areas, hyperpigmentation, hypertrichosis, and porphyrinuria. The condition was called kara yara or 'black sore.' Many of the breast-fed children under the age of 2 years whose mothers had ingested HCB-treated grain died from a disease known as pembe yara or 'pink sore.' In this follow-up study of 252 patients, 20-30 years postexposure, there were 162 males and 90 females, with an average current age of 35.7 years, an average of onset of 7.6 years, and a duration of 2.2 years. Many patients had dermatologic, neurologic, and orthopedic symptoms and signs. The observed clinical findings include scarring of the face and hands (83.7％), hyperpigmentation (65％), hypertrichosis (44.8％), pinched facies (40.1％), painless arthritis (70.2％), small hands (66.6％), sensory shading (60.6％), myotonia (37.9％), cogwheeling (41.9％), enlarged thyroid (34.9％), and enlarged liver (4.8％). Urine and stool porphyrin levels were determined in all patients, and 17 have at least one of the porphyrins elevated. A total of 56 specimens of human milk obtained from mothers with porphyria were analyzed for HCB. The average value was 0.51 ppm in HCB-exposed patients compared to 0.07 ppm in unexposed controls. Offspring of mothers with three decades of HCB-induced porphyria appear normal. 1989 Academic Press, Inc.

Synthesis of a magnetic micro/nano Fe_xO_y-CeO_2 composite and its application for degradation of hexachlorobenzene

A micrometer-sized nanostructured,magnetic,ball-like FexOy-CeO2 composite was synthesized through an ethylene-glycol mediated process.The synthesized samples were characterized by scanning electron microscopy combined with energydisperse X-ray analysis,transmission electron microscopy and X-ray powder diffraction.In the synthesis system,polyethylene glycol (PEG) and urea were found to play significant roles in the formation of the micrometer-sized spherical architecture of the precursor.The details of morphology and particle size could be changed with the initial concentration of Fe(NO3)3-9H2O and Ce(NO3)3-6H2O as the reactants.The magnetic FexOy-CeO2 composite with a similar morphology was readily obtained by calcination from the precursor.The characterization of transmission electron microscopy showed the calcined ball-like architecture was a highly porous structure consisting of many nanoparticles.Because of the micrometer-sized nanostructure and the multi-components as well as the magnetism,the as-obtained FexOy-CeO2 composite showed better activity and potentially easy recovery for the harmless degradation of hexachlorobenzene (HCB).

Rapid degradation of hexachlorobenzene by micron Ag/Fe bimetal particles

The feasibility of the rapid degradation of hexachlorobenzene （HCB） by micron-size silver （Ag）/iron （Fe） particles was investigated.Ag/Fe particles with different ratios （0,0.05%,0.09%,0.20%,and 0.45%） were prepared by electroless silver plating on 300 mesh Fe powder,and were used to degrade HCB at different pH values and temperatures.The dechlorination ability of Fe greatly increased with small Ag addition,whereas too much added Ag would cover the Fe surface and reduce the effective reaction surface,thereby decreasing the extent of dechlorination.The optimal Ag/Fe ratio was 0.09%.Tafel polarization curves showed that HCB was rapidly degraded at neutral or acidic pH,whereas low pH levels severely intensified H2 production,which consumed the reducing electrons needed for the HCB degradation.HCB degradation was more sensitive to temperature than pH.The rate constant of HCB dechlorination was 0.452 min-1 at 85℃,50 times higher than that at 31℃.HCB was degraded in a successive dechlorination pathway,yielding the main products 1,2,4,5-tetrachlorobenzene and 1,2,4-trichlorobenzene within 2 hr.

机械力化学法活化铝系硅酸盐矿物降解六氯苯机理研究

针对六氯苯(HCB)在土壤中长期存在难以降解的问题,本研究基于机械力化学法,系统地探究土壤中固有成分铝系硅酸盐(高岭土、白云母和膨润土)对HCB的降解效果,讨论了球磨转速、球磨时间、HCB初始浓度等条件对HCB降解效率的影响。在HCB浓度为50 000 mg/kg的条件下,600 r/min球磨2 h后,铝系硅酸盐矿物对HCB去除能力由大到小依次为高岭土、白云母、膨润土,高岭土和白云母对HCB的去除率分别为90.13%、85.72%,膨润土几乎不降解HCB。HCB的去除率随着球磨时间增加而增加,与转速呈正相关。HCB初始浓度的降低有利于HCB的降解和脱氯效率,当HCB处于高浓度水平50 000 mg/kg时,高岭土和白云母的脱氯效率较低;当HCB处于低浓度水平2 500 mg/kg时,高岭土和白云母的脱氯效果提高,高岭土的脱氯效果优于白云母。利用ESR检测自由基信号发现,高岭土在机械力化学作用下产生了高活性氧类自由基,而白云母和膨润土未产生自由基。利用GC-MS分析HCB降解中间产物,当高岭土作为添加剂时,产生的自由基导致HCB的C—Cl发生断裂,经过连续脱氯过程,HCB的稳定结构被打破,形成了一系列不稳定的含Cl中间产物。综上所述,铝系硅酸盐矿物在机械力化学作用下能够高效降解HCB,而且便宜易得,不会造成二次污染,具有广泛的应用潜力。

人参中3种农药残留分布规律及短期膳食风险评估

为了解人参不同部位中农药残留分布规律及膳食风险,分别取黑龙江省鸡东市2、3、4年参,虎林市2、3、4、5、6年参,针对其芦头、主根及须根建立了气相色谱-质谱联用(GCMS)检测技术,分别测定了其中五氯硝基苯、六氯苯及毒死蜱的残留量,并就人参中3种农药残留的短期膳食风险进行了评估。72份人参样品中,五氯硝基苯检出率为74%,检出残留量在0.005~0.062 mg/kg之间;六氯苯检出率为78%,残留量在0.057~0.150 mg/kg之间;毒死蜱检出率为61%,残留量在0.018~0.073 mg/kg之间。2020版《中国药典》规定人参中五氯硝基苯和六氯苯的最大允许残留限量(MRL)均为0.1 mg/kg,所检测样品中,虎林市5、6年参芦头及6年参主根中六氯苯的残留量超过了该限量标准,超标率分别为2.8%、5.6%和2.8%。总体而言,农药残留水平随人参种植年份的增加而升高,人参各部位中累积的农药残留量由高到低分别为芦头>主根>须根,同时其短期膳食风险商(RQST)远小于100%,说明通过人参摄入的农药残留对人体不会产生不可接受的短期膳食暴露风险。

六氯苯有机氯农药污染土壤修复技术研究

为探究化学氧化、化学淋洗及热脱附技术对有机氯农药污染场地的修复效果,选取六氯苯污染土壤为研究对象,分别考察三种修复技术及联合修复技术,并按照GB36600-2018《土壤环境质量建设用地土壤污染风险管控标准(试行)》评估修复效果。结果表明,化学氧化和化学淋洗修复技术均可以实现低浓度污染土壤(25~36.4 mg/kg)中六氯苯的含量低于建设用地二类用地管制值10 mg/kg;热脱附温度150℃,停留时间60 min时可以实现高浓度污染土壤(67 mg/kg)中六氯苯的含量低于一类建设用地的管制值标准3.3 mg/kg;联合修复技术较单一修复技术可以大大提高土壤中六氯苯的去除效果,其中化学氧化联合热脱附修复后六氯苯含量低于二类用地的筛选值1 mg/kg。由此可见,联合修复技术修复六氯苯污染土壤是可行的,具有一定的研究应用价值。

γ辐照降解六氯苯(HCB)的研究

研究了在不同溶剂体系及不同浓度添加物的联合作用下,六氯苯经γ射线辐照的降解.结果表明,六氯苯在丙酮和水混合溶剂中能得到有效降解,最大降解率达93%,在正己烷溶剂中也有部分降解,多数生成五氯苯.CO2-3与H2O2提高六氯苯的降解效率,TritonX 100、NO-2降低六氯苯的降解效率,且浓度越大作用越明显.3与NO-

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 [1 1 0 .4 μg (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 .

处理温度和时间对六氯苯污染土壤热解吸修复的影响

以山东潮土作为供试土壤,模拟HCB(六氯苯)污染土壤的热解吸试验研究.考察处理温度和时间2个主要影响因素对热解吸后土壤中HCB的去除率及其热解产物变化的影响.结果表明:随处理温度的升高和处理时间的延长,HCB的去除率逐渐增大,在处理温度400℃、处理时间10 min时,HCB的去除率达到94.2%;在处理温度450℃、处理时间60 min时,HCB的去除率达到99.4%,去除效果明显,w(HCB)达到HJ 350—2007《展览会用地土壤环境质量评价标准》的A级标准限值(≤0.66mgkg);继续升高处理温度和延长处理时间对HCB的去除率改变不大.HCB的热解吸过程不仅是HCB的物理分离过程,也存在HCB的还原脱氯过程,HCB的热解产物主要为1,3,5-TCB(1,3,5-三氯苯)和1,2,4-TCB(1,2,4-三氯苯);处理温度450℃、处理时间60 min为该污染土壤较为合适的热解吸运行参数.

多金属氧酸盐杂化催化剂光催化降解有机杀虫剂六氯苯

通过自组装技术制备了一系列多金属氧酸盐 有机胺 分子筛杂化催化剂K5[M (H2 O)PW11O3 9] (EtO) 3 Si(CH2 ) 3 NH2 MCM 4 8,用XRD ,ICP AES ,UV/DRS ,FT IR ,3 1PMASNMR和N2 吸附等手段对其组成和结构进行了表征 ,并以有机杀虫剂六氯苯为探针分子考察了其光催化活性 .结果表明 ,多金属氧酸盐杂化催化剂的光催化降解活性高于直接光解 ,能有效地降解污水中的六氯苯 ,且易分离 ,可循环使用 .

模拟水泥窑工艺对污染土壤热解吸尾气中六氯苯的去除效果

为了降低HCB(六氯苯)污染土壤热解吸修复的成本,分析了水泥窑处理技术去除污染土壤热解吸尾气中HCB的可行性,主要考察了处理温度、停留时间、φ(O2)和ρ(HCB)初始值对HCB去除的影响.结果表明:1随着处理温度的升高和停留时间的延长,HCB的去除率逐渐升高,其中,当处理温度≥800℃、停留时间≥2 s时,其去除率高于99.93%.2当处理温度为900℃、停留时间为2 s、ρ(HCB)初始值分别为1.70、17.00和85.00 mg/m3时,水泥窑处理后尾气中ρ(HCB)分别为0.60、0.78和1.50μg/m3,其与ρ(HCB)初始值并不成正比,说明ρ(HCB)初始值对HCB去除的影响较小;φ(O2)≥2%时对HCB去除的影响也较小.3水泥窑处理后,HCB的脱氯降解产物中仅有五氯苯被检出,ρ(五氯苯)最大值为1.20μg/m3;同时处理过程中伴有少量的二英产生,但ρ(二英)满足GB 30485—2013《水泥窑协同处置固体废物污染控制标准》要求.结果显示,模拟水泥窑工艺可有效去除污染土壤热解吸尾气中的HCB.

16S rDNA-RFLP分析六氯苯好氧降解菌群的结构及其多样性

从某化工厂排水沟底泥中取样,经2个月的富集驯化得到六氯苯好氧降解菌群。通过测定该微生物菌群在降解六氯苯过程中累积耗氧量、微生物生长曲线及Cl-浓度的变化,证明在好氧条件下该微生物菌群能够以六氯苯为唯一碳源和能源生长。当培养温度为30℃,pH为7.0时,该菌群能在18d内将无机盐培养基中浓度为4.5mg/L的六氯苯降解55%以上,降解速率达到137.5μg/(L.d)。对降解菌群提取总DNA,选择性扩增细菌16S rDNA片段,建立克隆文库。通过限制性内切酶(限制性内切酶HaeⅢ和RsaⅠ)分析,得到9种不同的谱型,其中3种谱型是主要谱型。对主要谱型的克隆子测序,结果表明,它们分别与Alcaligenes和Azospirillum菌属相似性最高。该菌群在去除环境中难降解的有机氯污染物方面具有应用前景。

六氯苯污染源水的饮用水应急处理工艺研究

针对长江水源地可能发生的六氯苯(HCB)突发污染事故,开展了应急处理工艺研究.考察了混凝剂聚合硫酸铁(PFS)投加量、KMnO4预氧化和木质粉末活性炭(PAC)吸附预处理对HCB去除效果的影响.根据静态试验,设计了三因素三水平正交试验,进一步考察了KMnO4氧化与PAC吸附联用预处理-混凝沉淀工艺去除HCB的效果.结果表明,常规处理无法有效去除HCB;单独KMnO4预氧化无法明显改善混凝沉淀对HCB的去除效果;PAC联用吸附预处理可明显提高去除效率.正交试验结果表明,在PAC,PFS,KMnO4投加量分别为40,5.0,0.5mg/L的最佳条件下,HCB去除率为98.97%,但浊度在2NTU以上.选取PAC吸附预处理-混凝沉淀工艺进行中试试验,结果表明,在PFS和PAC投加量分别为15mg/L和40mg/L时,HCB的去除率在98%以上,HCB剩余浓度和浊度分别在1μg/L和1NTU以下.

Fe^(2+)对辽河沉积物中DDT、HCB缺氧生物降解影响研究

测定了 Fe SO4 .7H2 O对辽河沉积物中滴滴涕 (DDT)、六氯苯 (HCB)缺氧生物降解的影响 .在无外加碳源的情况下 ,Fe SO4 .7H2 O对辽河沉积物中 DDT和 HCB的缺氧生物降解起抑制作用 .外加 Fe SO4 .7H2 O时 DDT、HCB的缺氧降解动力学常数 KDDT =0 .0 1 70 d- 1 ,KHCB=0 .0 0 69d- 1 ,均分别小于无外加 Fe SO4 .7H2 O时的 0 .0 2 1 3 d- 1 和 0 .0 0 77d- 1 .在有外加碳源葡萄糖或乙酸钠时 ,Fe SO4 .7H2 O对辽河沉积物中 DDT的缺氧生物降解起到了明显的促进作用 ;外加 Fe SO4 .7H2 O时 DDT的缺氧降解动力学常数 K葡萄糖 ,DDT=0 .0 3 89d- 1 ,K乙酸钠 ,DDT =0 .0 3 2 7d- 1 ,均分别大于无外加 Fe SO4 .7H2 O时的 0 .0 2 5 6d- 1和 0 .0 2 69d- 1 .但 Fe SO4 .7H2 O对 HCB在辽河沉积物中缺氧生物降解的影响则不大 。

六氯苯微生物降解研究进展

微生物降解已经成为当前六氯苯环境污染治理研究的重点和前沿。介绍了六氯苯的结构、物理化学性质、来源及其危害,分析了其微生物降解的可行性,从降解菌群的来源、降解途径及降解的影响因素等方面,对六氯苯的微生物好氧降解和厌氧降解进行了系统地归纳和总结,同时对今后六氯苯微生物降解的研究方向进行了展望。

钙化合物对前生体生成二噁英类的阻滞作用

针对城市生活垃圾焚烧(MSWI)过程中二噁英类的生成机制以及焚烧飞灰的组成,研究了MSWI飞灰中常见的钙化合物(CaO,Ca(OH)2,CaCl2,CaSO4及Ca(NO3)2)对前生体五氯酚(PCP)及六氯苯(HCB)生成二英类的阻滞作用.结果表明,280℃下加热2h,Ca(NO3)2,Ca(OH)2和CaO对PCP生成二噁英类的总阻滞效率分别为93.7%,80.4%和98.9%,而CaCl2和CaSO4几乎没有效果.CaO对PCP和HCB混合物生成二噁英类物质同样具有良好的阻滞效果.另外,探讨了上述钙化合物对PCP及HCB生成二噁英类的阻滞作用机理.

六氯苯胁迫下2种湿地植物根际土壤微生物数量与酶活性变化

为揭示人工湿地植物根际效应对氯苯类化合物生物降解的影响,选取典型湿地植物芦苇(Phragmites australis)和香蒲(Typha angustifolia),模拟室外人工湿地微宇宙系统,研究六氯苯(hexachlorobenzene,HCB)胁迫下根际土壤中微生物数量和酶活性变化。结果显示:芦苇和香蒲表现出明显的根际效应,根际土壤微生物(细菌、真菌、放线菌)数量以及土壤脱氢酶(DEH)、过氧化氢酶(CAT)和多酚氧化酶(PPO)活性均表现为根际土大于非根际土,且香蒲组土壤微生物数量和酶活性均显著高于芦苇组(P<0.05);芦苇和香蒲组土壤中HCB含量与微生物数量和3种酶活性呈负相关,香蒲组土壤中HCB含量与DEH活性和PPO活性呈显著负相关(P<0.05)。研究表明随着芦苇和香蒲根际土壤微生物数量与酶活性的增加,2种植物的根际效应增强,进而促进湿地系统对HCB的去除。

HCB与γ-HCH在辽河沉积物中的缺氧降解动力学

为全面认识多氯有机物在天然水沉积物中的转化行为,利用超声波发生仪萃取沉积物样品,采用气相色谱仪(Ni63-ECD)定量分析,在缺氧条件下,测定了辽河沉积物中六氯苯(HCB)、γ-HCH的微生物降解速率.在单个培养体系中,测定出不外加有机碳源,外加葡萄糖和乙酸钠3种条件下HCB、γ-HCH的缺氧降解符合准一级动力学方程,动力学常数分别为HCB:k(不外加有机碳源)=0.0014d-1,k(葡萄糖)=0.0033d-1,k(乙酸钠)=0.0052d-1;γ-HCH:k(不外加有机碳源)=0.0454d-1,k(葡萄糖)=0.1143d-1,k(乙酸钠)=0.1451d-1.在2种氯代物混合培养体系中,HCB、γ-HCH的降解速率均有所下降.经GC-MS测定,三氯苯、二氯苯分别是HCB、γ-HCH的主要降解产物.