Phototransformation of chlorimuron-ethyl on leaf surface

Chlorimuron-ethyl, a post-emergent herbicide selectively used in soybean and maize, degrades mainly through chemical hydrolysis. Photolysis has also an important role in the degradation of this compound. Phototransformation of chlorimuron-ethyl takes place through the cleavage of the sulfonylurea bridge, dechlorination, de-esterification and cyclization. Enzymatic de-esterification usually takes place in plant system to liberate the free acid, chlorimuron, which, in fact, inhibits the acetolactate synthase enzyme. In the non-enzymatic environment, de-esterification generally does not occur at normal pH and in moisture-free medium. But on the leaf surface of maize crop de-esterification of chlorimuron-ethyl takes place. The moisture deposited on leaf surfaces by virtue of evapo-transpirational loss of water may cause the de-esterification of chlorimuron-ethyl to the free acid, chlorimuron.     

Photodegradation of the organophosphorus pesticides chlorpyrifos,fenamiphos and vamidothion in water

The photodegradation of the pesticides chlorpyrifos, fenamiphos and vamidothion in water containing 2–4% methanol was examined. Acetone (5%) was added as photosensitizer in the photolysis of vamidothion. A suntest apparatus equipped with a xenon arc lamp which exhibits a radiation very close to natural sunlight was employed. Analyses were performed by direct injection of the water samples containing the photoproducts into a liquid chromatograph with diode array and thermospray mass spectrometric detection. The major photodegradation products were identified by matching their diode‐array spectra with the corresponding spectra of the authentic standards, their retention times and the spectra obtained using positive and/or negative thermospray mass spectrometry. 3,5,6‐trichloro‐2‐pyridinol, fenamiphos sulfoxide and vamidothion sulfoxide were the major photodegradation products from chlorpyrifos, fenamiphos and vamidothion, respectively.     

水环境中抗生素的光降解研究进展

抗生素的大量使用已经成为了全球环境问题.由于其在环境水体中难以被微生物降解,且能导致细菌抗药性越来越受到关注.光降解是污染物在水环境中非常重要的非生物降解途径.本文介绍了水环境中抗生素的直接、间接和自敏化光降解动力学,着重阐述了抗生素的光降解过程的影响因素、降解产物和可能降解途径等最新研究成果,指出抗生素光降解产物的分离提取与结构鉴定,以及预测抗生素降解过程的动力学模型构建将成为今后主要的研究方向和趋势.     

丁烯氟虫腈光降解反应过程及机理

考察了乙腈/水混合溶液中丁烯氟虫腈的光解速率及水体中主要溶解性物质对其光解的影响,通过产物鉴定及模拟计算判定了丁烯氟虫腈光降解反应机理.结果表明,模拟日光下丁烯氟虫腈快速发生光降解,纯水中反应半衰期为17.34 min.腐殖酸通过竞争光吸收来抑制丁烯氟虫腈的光解,NO3-和Cl-对其光解无影响.丁烯氟虫腈光解反应位点位为亚砜基团上的硫原子,主要产物为脱硫化物(MW 442.0),砜化物(MW 506.0)及2种硫化物(MW 473.9和405.8).键级和键长分析也证实丁烯氟虫腈硫原子连接的化学键不稳定,易发生断裂重排反应,生成上述转化产物.     

PCDDs在氯仿溶液中的紫外光解

使用ＮＤＣ－３型化学反应仪、３００Ｗ汞灯和１５ｍｌ反应管，于４３℃进行了２，３，７，８－ＴＣＤＤ，１，２，３，７，８－Ｐ５ＣＤＤ，１，２，３，４，７，８－ＨｘＣＤＤ，１，２，３，４，６，７，８－ＨｐＣＤＤ和ＯＣＤＤ在氯仿溶中的紫外光解，其一级反应速率常数测得值依次为０．５４，０．２９，０．１５，０．１５和０．１９ｍｉｎ＾－１，反应半衰期ｔ１／２均在５ｍｉｎ以内，还原脱氯是主要的光解途径，并有大量低     

不同生物质燃烧排放多环芳烃及糖醇类化合物的模拟研究

选择水稻、小麦、玉米及棉花秸秆与马尾松枝,采集模拟燃烧时排放的PM2.5,分析PM2.5中多环芳烃(PAHs)和糖醇类化合物的含量,获得PM2.5及负载的两类化合物的排放因子;采用500 W汞灯直接照射收集了PM2.5的尘膜,获得了中、高环PAHs及左旋葡聚糖的光解动力学.结果表明,PM2.5的排放因子介于(2.26±0.60)g·kg-1(马尾松枝)~(14.33±5.26)g·kg-1(玉米秸秆)之间;19种PAHs的排放因子介于(0.82±0.21)mg·kg-1(马尾松枝)~(11.14±5.69)mg·kg-1(棉花秸秆)之间,且以4环类PAHs所占比例最高,介于51%~71%之间(其中马尾松枝燃烧时惹烯的排放因子最大);9种糖醇类化合物的排放因子范围为(52.34±50.16)mg·kg-1(水稻秸秆)~(238.81±33.62)mg·kg-1(小麦秸秆),且都以左旋葡聚糖占绝对优势(72%~96%).光照模拟显示,目标化合物的光照损失都遵循拟一级动力学,其中≥4环的PAHs的光解速率常数随着尘膜中PAHs的负载量增大而减小,来源特征比值Flua/(Flua+Py)和Ip/(Ip+Bg P)相对稳定,而左旋葡聚糖的光解速率常数为0.004 5 min-1,与苯并[a]蒽的光解速率常数(0.004 1~0.005 0 min-1)接近.     

UV-vis光照下唑类抗菌药氟康唑的光化学反应类型

以唑类抗菌药氟康唑为模型化合物,考察了其在纯水中的光降解动力学和光化学反应类型,发现模拟日光(λ>290nm)照射下氟康唑未发生光解,在UV-vis(λ>200 nm)光照下,氟康唑发生了光降解并服从准一级反应动力学.采用活性氧物种猝灭实验和竞争动力学方法,研究发现氟康唑发生了直接光解和·OH参与的自敏化光解,氟康唑与.OH的反应速率常数为(5.95±0.58)×109L·(mol·s)-1,表层水体中相应的半减期为(32.41±3.16)h·通过鉴定光解产物,得知氟康唑发生了脱氟、光致水解、光氧化等光化学反应.     

Abiotic degradation of four phthalic acid esters in aqueous phase under natural sunlight irradiation

Abiotic degradability of four phthalic acid esters (PAEs) in the aquatic phase was evaluated over a wide pH range 5–9. The PAE solutions in glass test tubes were placed either in the dark and under the natural sunlight irradiation for evaluating the degradation rate via hydrolysis or photolysis plus hydrolysis, respectively, at ambient temperature for 140 d from autumn to winter in Osaka, Japan. The e ciency of abiotic degradation of the PAEs with relatively short alkyl chains, such as butylbenzyl phthalate (BBP) and di-nbutyl phthalate (DBP), at neutral pH was significantly lower than that in the acidic or alkaline condition. Photolysis was considered to contribute mainly to the total abiotic degradation at all pH. Neither hydrolysis nor photolysis of di-ethylhexyl phthalate (DEHP) proceeded significantly at any pH, especially hydrolysis at neutral pH was negligible. On the other hand, the degradation rate of diisononyl phthalate (DINP) catalyzed mainly by photolysis was much higher than those of the other PAEs, and was almost completely removed during the experimental period at pH 5 and 9. As a whole, according to the half-life (t1=2) obtained in the experiments, the abiotic degradability of the PAEs was in the sequence: DINP (32–140 d) > DBP (50–360 d), BBP (58–480 d) > DEHP (390–1600 d) under sunlight irradiation (via photolysis plus hydrolysis). Although the abiotic degradation rates for BBP, DBP, and DEHP are much lower than the biodegradation rates reported, the photolysis rate for DINP is comparable to its biodegradation rate in the acidic or alkaline condition.     

基于DFT计算和实验研究无机氮对水中萘普生及其产物光解的影响

萘普生(NP)是一种广泛使用的消炎镇痛类药.本文研究了水中不同形态无机氮对萘普生及其两种重要的光解中间产物NP_1和NP_2光降解的影响.结果表明,NH~+_4对于NP及产物的光解几乎没有影响,NO~-_2和NO~-_3对NP、NP_1和NP_2的光解均表现出抑制作用.NO~-_2和NO~-_3对NP的影响主要是光屏蔽效应,而对NP_1和NP_2光解影响的主导因素是由光化学环境中产生的·NO、·NO_2同·OH的竞争关系造成的间接抑制.光化学环境中·OH、·NO_2、·NO氧化NP_1和NP_2的化学反应活化能垒呈现上升趋势(NP_1:7.0、21.2、54.4 kcal·mol~(-1);NP_2:34.5、47.1、70.3 kcal·mol~(-1)).活化能垒的差异表明,光化学反应体系中生成的·NO_2和·NO将会导致反应速率下降,这也诠释了NO~-_2和NO~-_3对NP_1和NP_2光解抑制的差异性.     

重金属离子存在下黏土矿物表面蒽的光化学降解性能

探讨了蒽在Cu、Pb、Zn、Cd、Ni等重金属离子饱和的黏土矿物表面的光降解行为,研究了重金属离子种类,黏土矿物种类、p H、自由基捕获剂和氧气对黏土表面蒽降解速率的影响.研究表明,不同种类金属离子饱和的蒙脱石表面蒽的降解速率Cu2+Pb2+Zn2+Cd3+Ni2+Na+,其中Cu-蒙脱石表面蒽的光降解速率达78.8%;黏土矿物CEC值越高,可交换的铜离子含量越大,对蒽的光降解速率的促进作用越明显;Cu-蒙脱石表面蒽的光降解速率随p H值增大而逐渐减小,p H≥8.71时,蒽的降解率为0,其变化规律与Cu2+随p H值的存在形态的变化趋势相吻合.此外,蒽在Cu-蒙脱石表面的光降解速率随加入的对苯醌增多而减小,对苯醌含量达2.0 mg·g-1时蒽的降解率为0,无氧条件下蒽的降解率为0,推测该反应体系中有氧化活性自由基(O-2·)的产生,可能为光催化氧化降解起始因素之一.