连续活性污泥法降解壬基酚聚氧乙烯醚废水的研究

采用连续活性污泥法对壬基酚聚氧乙烯醚NP-10(简称NP-10)废水的生物降解性能进行了研究,考察了水力停留时间(HRT)对其生物降解的影响。结果表明:(1)在生物降解的稳定期,HRT为3、6h的初级生物降解度平均分别为96.5%、96.2%,最终生物降解度平均分别为84.8%、87.3%。这表明,NP-10较易初级生物降解,大部分NP-10可以最终生物降解;延长HRT对其初级生物降解基本没有影响,对其最终生物降解影响不大。(2)采用高效液相色谱法检测了苯环的降解情况。10～20d,HRT为3、6h的苯环降解度平均分别为58.7%、75.4%,说明部分苯环可被降解,苯环降解度随HRT的延长而增加。(3)在稳定期,对不同HRT的空白曝气罐与NP-10曝气罐中的微生物进行鉴定和计数后发现,空白曝气罐与NP-10曝气罐中的微生物在种类和数量上都存在一定的差异;不同HRT的NP-10曝气罐内的微生物情况基本一致。     

壬基酚聚氧乙烯醚在膜-生物反应器中的归趋

综述了环境内分泌干扰物壬基酚聚氧乙烯醚的化学性质、环境释放机制以及其对环境构成的危害,归纳了壬基酚及其短链聚氧乙烯醚（NPnEO）在膜-生物反应器（MBR）中的迁移转化规律,分析了其生物降解性和降解机理,探讨了MBR中活性污泥对其吸附能力和膜的截留能力,讨论了包括厌氧或好氧条件下的温度、水力停留时间、污泥停留时间等因素对于其降解过程的影响。     

壬基酚聚氧乙烯醚在印染废水处理工艺中的去除研究

为减少印染助剂壬基酚聚氧乙烯醚(nonylphenol ethoxylates,NPEO)及其降解产物壬基酚(nonylphenol,NP)随印染废水进入水体造成的不利环境影响,对2种常规印染废水处理净水工艺处理含NPEO的模拟印染废水效率开展了研究。研究发现,结合厌氧水解和曝气氧化的生物处理工艺能迅速地将废水中NPEO去除,去除率达到90%以上,但排水中残余一定含量的NP、短链NPEO和短链壬基酚聚氧乙烯醚酸酯(nonylphenol polyethoxycarboxylate,NPEC),在减少排水中NP、短链NPEO和短链NPEC浓度方面,接触氧化法比活性污泥法效果更好。排水中的NP和短链NPEO来自厌氧水解阶段长链NPEO的降解;减少排水中NP、短链NPEO需要减少厌氧水解阶段产生的短链NPEO。     

辛基酚聚氧乙烯醚高效降解混合菌L9的固定化及其条件优化

为彻底高效解决辛基酚聚氧乙烯醚的环境危害,以海藻酸钠和聚乙烯醇为载体,以辛基酚聚氧乙烯醚高效降解混合菌L9为材料,采用海藻酸钠、聚乙烯醇和聚乙烯醇+海藻酸钠制备固定化混合菌L9,研究了各固定化混合菌L9颗粒的机械稳定性与化学稳定性,结果表明,利用聚乙烯醇+海藻酸钠制得的固定化混合菌L9颗粒具有较高的机械和化学稳定性。利用正交实验对聚乙烯醇+海藻酸钠固定化条件进行优化,得到聚乙烯醇浓度8.0%,海藻酸钠浓度1.0%,交联剂2%氯化钙的饱和硼酸溶液,包埋菌量与包埋剂的体积比值2：1,交联时间24 h为聚乙烯醇+海藻酸钠固定化混合菌L9的最佳条件。考察不同环境条件（温度、pH值和底物浓度）对固定化混合菌L9与游离混合菌L9降解辛基酚聚氧乙烯醚的影响,结果显示,固定化混合菌L9对各环境因素（温度、pH值和底物浓度）的耐受范围都比游离混合菌L9宽,在实际环境应用中更能保持稳定的生物活性,研究结果对解决当前制革、洗涤、农药等行业产生的辛基酚聚氧乙烯醚的环境污染问题具有指导作用。     

超声波/Fenton工艺降解微量邻苯二甲酸二甲酯和壬基酚效能的研究

研究了在超声波、Fenton不同体系中邻苯二甲酸二甲酯(DMP)和壬基酚(NP)的降解效果.通过正交实验得到超声波/Fenton工艺各个因素影响程度的大小为:H2O2投加量＞初始pH＞反应时间＞Fe2+投加量＞超声功率.最后得到降解250mL质量浓度为100 μg/L的DMP的最佳条件:H2 O2投加量为2 mmol/L、Fe2+投加量为0.40 mmol/L、初始pH为3.00、超声功率为1 800W、反应时间为120 min,降解率可达到85.96％;降解250mL质量浓度为100 μg/L的NP的最佳条件:H2O2投加量为4mmol/L、Fe2+投加量为0.50 mmol/L、初始pH为3.00、超声功率为1 800W、反应时间为120 min,降解率可达到78.70％.     

缓释氮源的固定化Rhodococcus sp.W7颗粒处理焦化废水

本研究将固定化微生物与氮源缓释相结合,以提高一般固定化微生物在氮源缺乏环境中的生物降解效率。利用尿素作为缓释氮源,通过将聚乙烯醇-海藻酸钠混合凝胶(包含尿素)在3% CaCl₂ 饱和硼酸溶液中一次交联,在0.5 mol·L⁻¹硫酸钠溶液中二次交联,最终制得的缓释尿素固定化微生物颗粒包封率高达98%以上,溶胀率在15%~25%,同时有较高的机械强度。在无氮条件下,颗粒可在4、8、12 h内分别完成对100 mg·L⁻¹苯酚、吡啶或喹啉的降解;在高碳氮比的模拟焦化废水环境下,可在6 h内完成对100 mg·L⁻¹苯酚、10 mg·L⁻¹吡啶及10 mg·L⁻¹喹啉混合底物的降解。另外,固定化微生物颗粒所包含的尿素提供的氮源能满足固定化微生物每天降解100 mg·L⁻¹苯酚并持续20 d。以上研究结果表明所制备的缓释尿素固定化微生物颗粒可应用于氮源匮乏的污水治理中并有较好的应用效果。     

铋酸钠基环境复合催化材料的制备及降解壬基酚的研究

高级氧化技术是重要的水处理技术之一。以铁掺杂NaBiO3为基础催化剂,通过和氧化石墨烯负载,制备出一种石墨烯-铁-铋酸钠基复合催化剂(记为G-Fe-NaBiO3)。并选取环境激素壬基酚(NP)为底物,研究了G-Fe-NaBiO3可见光-类Fenton催化氧化降解NP的动力学过程,探究了催化剂用量、过氧化氢浓度、pH等对NP降解效果的影响。结果表示,过氧化氢为15mmol/L,催化剂用量为0.8g/L,pH为6,温度为25℃时,对NP的降解率高达99%。本研究可为水体中痕量有机污染物的降解提供一定的理论参考。     

氯氰菊酯降解菌CY22-7的分离鉴定及降解特性研究

从采集的多种土壤样品中.获得了19株在3种筛选平板上均生长良好的候选氯氰菊酯降解菌.通过生理生化特性鉴定和16S rDNA序列的测定及比对.将其中的氯氰菊酯降解菌CY22-7鉴定为中华根瘤菌属(Sinorhizobium sp.).同时,对氯氰菊酯降解菌CY22-7的降解特性研究结果表明:(1)氯氰菊酯降解菌CY22-7以5%(体积分数)的接种鼍接种到氯氰菊酯起始质量浓度为100 mg/L的氯氰菊酯乙醇培养基后,于200 r/min、30℃摇床中培养.经过6 d的培养,氯氰菊酯降解菌CY22-7降解了约60%的氯氰菊酯.(2)加人外源营养物质有利于促进氯氰菊酯的降解.其中,葡萄糖和酵母提取物的促进作用最为明显.(3)氯氰菊酯降解菌CY22-7降解氯氰菊酯的最适温度为30℃,最佳pH为6.0.     

Citrobacter sp.CK3对活性红KN-3B的脱色反应动力学研究

采用脱色菌Citrobacter sp. CK3,以活性红KN-3B染料为处理对象,在厌氧批式反应条件下,系统考察了pH值,温度和染料浓度对脱色反应速度的影响;通过动力学模拟及反应过程中染料的UV-Vis扫描图分析,探讨了脱色反应机理。结果表明:Citrobacter sp. CK3对活性红KN-3B的脱色反应的适宜pH为7～9;脱色反应速度在温度为32℃时达到最大。染料初浓度从57 mg/L逐渐增大到458 mg/L时脱色率逐渐降低。脱色过程中染料的偶氮键发生断裂,脱色反应符合二级反应动力学。     

金属离子对菌株JY01生长和苯酚降解性能的影响研究

金属可能通过生理和生态两方面对微生物的苯酚降解过程产生重要影响.为了提高芽孢杆菌Bacillus sp.JY01(以下称菌株JY01)的苯酚降解效率,探讨了6种金属离子(Ba2+、Cu2+、Co2+、Fe3、Zn2+、pb2+)对其生长和苯酚降解性能的影响.结果表明,在质量分数为0.001％～0.050％时,Cu2+、Zn2+、Co2、Fe3+、Ba2+、pb2+对菌株JY01的生长和苯酚降解均有抑制作用,并且抑制作用总体随金属离子浓度的升高而增强,当6种金属的质量分数分别达到0.005％时,菌株JY01对苯酚的降解能力为Ba2+ ＜Cu2+ ＜Co2+ ＜Fe3+ ＜Zn2+ ＜pb2+;金属离子通过影响菌株JY01的生长状况来影响其苯酚降解性能;很多金属离子对菌株JY01生长有明显抑制作用,因此在实际生物处理含苯酚废水时,要考虑废水中金属离子对降解菌生长状况的影响.     

反相高效液相色谱法测定污水中壬基酚聚氧乙烯醚总量

建立了固相萃取一反相液相色谱一荧光检测法分析污水中壬基酚聚氧乙烯醚总量的方法.固相萃取采用Wa-ters Oasis HLB固相萃取柱(30 μg×60 mg×3 mL),6 mL二氯甲烷/甲醇(90/10,V/V)混合溶剂洗脱,洗脱液用氮吹仪浓缩至1 mL,回收率为99.68%.采用ZORBAX Eclipse XDBC-18(4.6 mm×150 mm,5 μm)反相色谱柱,甲醇/水为流动相,流速1.0 mL/min,以每分钟增加2.5%的梯度陡度进行洗脱,流动相中甲醇比例由70%增加到100%,柱温23℃,进样量15μL.荧光检测器的激发波长230 nm,发射波长313 nm.采用外标法定量.该方法的空白加标和污水样品加标回收率均在90%以上,标准偏差小于10%,定量下限为0.97～1.90 μg/L.利用该方法分别对污水处理厂进水水样、二级处理出水水样、再生水水样进行了测定,测定结果的准确度和精密度满足痕量分析的要求.     

Shewanellasp．XB缺氧反硝化降解苯酚

苯酚的生物降解一直受到关注。以苯酚为惟一电子供体,研究了Shewanellasp．XB对苯酚的缺氧降解特性。研究结果表明,在反硝化条件下,当C／N为13．3时,苯酚可以完全降解,NO2--N积累量很少。另外,当加入氧化还原介体,如核黄素3μmol／L、AQDS0．01mmol／L、AQS0．05mmol／L和LQ0．01mmol／L时,苯酚降解速率分别为不加介体时的1．45、1．77、1．67和1．63倍。当以氯化铵代替硝酸盐时,苯酚也能进行厌氧发酵降解。另外,菌株XB反硝化降解苯酚可能是厌氧和好氧降解的混合过程。     

Biodegradation of acetochlor by a newly isolated Achromobacter sp. strain D-12

A highly effective acetochlor-degrading bacterial strain (D-12) was isolated from the soil of a pesticide factory. The strain was identified as Achromobacter sp. based on its 16S rRNA gene sequence. The strain D-12 optimally degrades acetochlor at a pH of 7.0 and a temperature of 30°C in a mineral salts medium (MSM). Approximately 95% of acetochlor was degraded by the stain treated at a concentration of 10 mg L^?1 after 5 days of incubation. A chiral high performance liquid chromatography (HPLC) system was used to study the enantioselectivity during the process. However, no obvious enantioselective biodegradation was observed. The primary biodegradation acetochlor products were identified by high-performance liquid chromatography-mass spectroscopy (HPLC-MS) and gas chromatography-mass spectrometry (GC-MS). The results indicated that the strain D-12 could be applied in the bioremediation of an acetochlor-polluted environment.     

Shewanella sp.XB缺氧反硝化降解苯酚

苯酚的生物降解一直受到关注。以苯酚为惟一电子供体,研究了Shewanella sp.XB对苯酚的缺氧降解特性。研究结果表明,在反硝化条件下,当C/N为13.3时,苯酚可以完全降解,NO-2-N积累量很少。另外,当加入氧化还原介体,如核黄素3μmol/L、AQDS 0.01 mmol/L、AQS 0.05 mmol/L和LQ 0.01 mmol/L时,苯酚降解速率分别为不加介体时的1.45、1.77、1.67和1.63倍。当以氯化铵代替硝酸盐时,苯酚也能进行厌氧发酵降解。另外,菌株XB反硝化降解苯酚可能是厌氧和好氧降解的混合过程。     

Alcaligenes sp.YF11菌对杀灭菊酯的降解机理

测定了降解菌Alcaligenessp.YF11对不同浓度杀灭菊酯的降解及其降解途径。在纯培养系统中,Alcaligenessp.YF11对100mg／L的杀灭菊酯的降解符合零级动力学特征,其降解速率为2．1mg／L·h;50mg／L的杀灭菊酯在24h的降解率为87.5％;10mg／L的杀灭菊酯10h的降解率为71．0％。Alcaligenesso．YF11对杀灭菊酯的降解为矿化作用。     

Biodegradation of triazine herbicide metribuzin by the strain Bacillus sp. N1

By enrichment culturing of soil contaminated with metribuzin, a highly efficient metribuzin degrading bacterium, Bacillus sp. N1, was isolated. This strain grows using metribuzin at 5.0% (v/v) as the sole nitrogen source in a liquid medium. Optimal metribuzin degradation occurred at a temperature of 30ºC and at pH 7.0. With an initial concentration of 20 mg L^?1, the degradation rate was 73.5% in 120 h. If the initial concentrations were higher than 50 mg L^?1, the biodegradation rates decreased as the metribuzin concentrations increased. When the concentration was 100 mg L^?1, the degradation rate was only 45%. Degradation followed the pesticide degradation kinetic equation at initial concentrations between 5 mg L^?1 and 50 mg L^?1. When the metribuzin contaminated soil was mixed with strain N1 (with the concentration of metribuzin being 20 mg L^?1 and the inoculation rate of 10¹¹ g^?1 dry soil), the degradation rate of the metribuzin was 66.4% in 30 days, while the degradation rate of metribuzin was only 19.4% in the control soil without the strain N1. These results indicate that the strain N1 can significantly increase the degradation rate of metribuzin in contaminated soil.     

Isolation and characterization of an Alcaligenes sp. strain DG-5 capable of degrading DDTs under aerobic conditions

In this study, an Alcaligenes sp. strain DG-5 that can effectively degrade dichlorodiphenyltrichloro-ethanes (DDTs) under aerobic conditions was isolated from DDTs-contaminated sediment. Various factors that affect the biodegradation of DDTs by DG-5 were investigated. About 88 %, 65 % and 45 % of the total DDTs were consumed within 120 h when their initial concentrations were 0.5, 5 and 15 mg L^?1, respectively. However, almost no degradation was observed when their concentration was increased to 30 mg L^?1, but the addition of nutrients significantly improved the degradation, and 66 % and 90 % of the total DDTs were degraded at 336 h in the presence of 5 g L^?1 peptone and yeast extract, respectively. Moreover, the addition of 20 mM formate also enhanced the ability of DG-5 to transform DDTs, and its DDT transformation capacity (T_c) value was increased by 1.8 - 2.7 fold for the pure (p,p’-DDT or o,p’-DDT only) and mixed systems (p,p’-DDT, o,p’-DDT, p,p’-DDD and p,p’-DDE). Furthermore, it was found that competitive inhibition in the biodegradation by DDT compounds occurred in the mixed system.     

Isolation,identification, and acetochlor-degrading potential of a novel Rhodococcus sp. MZ-3

A new species of Rhodococcus, designated strain MZ-3, which could degrade acetochlor efficiently were isolated and identified. The isolate could degrade and utilize acetochlor as the sole source of carbon, nitrogen, and energy for growth. The optimal conditions for the degradation and growth of MZ-3 were pH 7.0 and 30°C. Under these conditions, this strain could completely degrade 200 mg/L of acetochlor within 12 h of incubation. During the biodegradation process, the enantioselectivity of the strain was investigated using a chiral high-performance liquid chromatography (HPLC) system. However, no obvious enantioselectivities were found. 2-chloro-N-(2-methyl-6-ethylphenyl) acetamide (CMEPA) was detected as the intermediate using liquid chromatography-mass spectrometry (LC-MS) analyses. Our results suggest that strain MZ-3 might be a promising microorganism for the bioremediation of acetochlor-contaminated environments because of its acetochlor-degrading performance.     

Mineralization of p-nitrophenol by a new isolate Arthrobacter sp. Y1

Arthrobacter sp. Y1, capable of metabolizing p-nitrophenol (PNP) as the sole carbon, nitrogen and energy source was isolated from activated sludge. The bacterium could tolerate concentrations of PNP up to 600 mg L^{? 1}, and degradation of PNP was achieved within 120 h of incubation. PNP and its metabolites were analyzed by high performance liquid chromatography (HPLC). The metabolite formed indicated that the organism followed the 4-nitrocathechol (4-NC) pathway for metabolism of this compound. The relevant degrading-enzyme was extracellular. Addition of other carbon source (glucose 0～ 30 g L^{? 1}) led to accelerated degradation. If the glucose concentration exceeded 30 g L^{? 1}, however, degradation was repressed. Spectrophotometry assay of the nitrite and genotoxic study showed that strain Y1 could detoxify PNP. Therefore, the present study may provide a basis for the development of the bioremediation strategies to remedy the pollutants in the environment.     

高效降酚菌株JY03的筛选及其降解特性研究

从绝缘材料厂排放的工业废水中分离得到一株能高效降解苯酚的菌株JY03,最高可耐受1.5 g/L的苯酚。通过形态观察、生理生化分析和16S rRNA序列分析,初步鉴定该菌属于棒状杆菌属(Corynebacterium sp. JY03)。JY03对苯酚降解最适条件为pH 7.5,温度32℃,苯酚浓度为0.6 g/L,时间为36 h,接种量6%,其降解率可达98.6%。该菌株在高效处理含酚废水方面具有广阔的应用前景。