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1.
广西百朗地下河水和沉积物中有机氯农药的分布特征 总被引:4,自引:2,他引:2
为了解典型岩溶地区广西乐业百朗地下河表层水和沉积物中有机氯农药的分布特征,采集地下河不同断面的水和沉积物样品,利用气相色谱仪测定了19种有机氯农药。结果表明:(1)百朗地下河表层水中19种有机氯农药总量(∑OCPs)浓度为1.95~71.45ng/L,HCHs和DDTs浓度分别为未检出至58.40ng/L和未检出至0.44ng/L;(2)沉积物中∑OCPs浓度为0.75~14.85ng/g,HCHs和DDTs浓度分别为0.11~3.52ng/g和0.03~2.90ng/g;(3)地下河表层水和沉积物中有机氯农药的分布与吸附作用、环境温度以及和地下河连通的天坑的底部的土壤侵蚀有关,即因温差作用,大气沉降的有机氯农药易富集在天坑底部(“冷陷阱效应”),并在土壤侵蚀作用下向水体移动,使地下河沉积物中有机氯农药浓度升高;(4)百朗地下河出口沉积物吸附系数最低,但水中有机氯农药浓度较高且种类最多,推测可能是地下河沉积物中因有机氯农药被释放而引起二次污染;(5)表层沉积物中大多数断面的异狄氏剂浓度及乐业县城附近断面的DDTs和DDD浓度在风险评估低值与风险评估中值之间,表明百朗地下河处于较低的生态风险水平;(6)目前,流域部分断面尚有新的γ-HCH(林丹)和DDTs农药输入。由于有机氯农药长期累积,可能对地下河生态系统造成危害,应采取防治措施。 相似文献
2.
重庆典型岩溶区地下河水体有机氯农药污染初步研究 总被引:7,自引:4,他引:3
利用GC-ECD对重庆典型岩溶区地下河水体中有机氯农药(OCPs)进行检测,结果表明,地下河水中OCPs浓度为3.41~51.34ng/L,均值为13.23ng/L;滴滴涕(DDTs)浓度为0.07~2.37ng/L,均值为0.72ng/L;六六六(HCHs)浓度为1.16~39.82ng/L,均值为7.89ng/L。南川湾滩地下河水体有机氯农药污染最为严重,其上游纸厂排放废水是影响该地下河有机氯农药污染的主要原因。与国内外其它河流相比较,研究区地下河水体有机氯农药含量处于中低水平。由于岩溶区特殊的二元结构,地表水体一旦受到污染,将直接影响到地下水体。因此,对岩溶地下河进行有机污染物的调查研究具有重要的现实意义 相似文献
3.
柳州岩溶地下河水体有机氯农药分布特征 总被引:6,自引:3,他引:3
采用气相色谱(配ECD检测器)对柳州鸡喇和龙寨两条岩溶地下河不同位置水体中18种有机氯农药(OCPs)组分进行分析。结果表明,除异狄氏剂醛外,其余17种OCPs均有不同程度检出,OCPs浓度变化范围为107.68~1101.55ng/L,均值为532.515ng/L。OCPs主要组分为:α-HCH、β-HCH、γ-HCH、δ-HCH、p,p'-DDE、o,p'-DDT、p,p'-DDD、p,p'-DDT、六氯苯、七氯、艾氏剂。其中DDTs和HCHs含量最高,二者之和占到总OCPs的75.8%~96%。对其污染源进行分析,发现地下河水体中DDTs主要源自土壤。HCHs来源相对复杂,可能源于工业品或者长距离大气运输,也可能是近期有林丹的输入使其浓度增高。与国内外各水体相比,本次研究的两条岩溶地下河有机氯农药含量相对较高。 相似文献
4.
广西桂林大岩洞岩溶洞穴土壤中有机氯农药的分布特征 总被引:2,自引:0,他引:2
首次对桂林岩溶区洞穴土壤中有机氯农药的污染状况进行了研究。结果表明,洞穴土壤受到了有机氯农药的轻度污染,其中大气传输对有机氯农药的贡献起主导作用。在17种有机氯农药中,以DDTs、HCHs和氯丹污染为主。在洞穴内部OCP总量为1.19~11.18 ng/g,远低于洞外土壤中的含量(11.41~23.62 ng/g)。在洞内土壤中,HCHs含量高于DDTs,在HCH四种同分异构体中,β-HCH占HCHs的比例远高于其他3种同分异构体。除β-HCH外,其他3种同分异构体的含量分布均匀,可能是由洞穴环境稳定、气候分带等因素造成的。在洞外土壤中,异构体百分比和示踪标志物比值表明周围可能有林丹扣三氯杀螨醇的新近输入。研究区六六六和滴滴涕主要来源于历史上使用的农药的残留。 相似文献
5.
重庆老龙洞地下河不同部位水体、表层沉积物有机氯农药含量及组成研究 总被引:2,自引:0,他引:2
为研究重庆老龙洞地下河不同部位水体、表层沉积物有机氯农药分布特征,用气相色谱-微池电子捕获检测器(GC-μECD)分析了样品中OCPs含量。结果表明:研究区水样、表层沉积物中OCPs检出率均为100 %,其浓度在时间上存在季节差异,水体中OCPs、DDTs、HCHs含量丰水期小于枯水期,而在表层沉积物中则表现为OCPs、HCHs丰水期大于枯水期,DDTs丰水期小于枯水期;在空间上则表现为水体中有机氯农药总体下游大于上游,而沉积物中则与之相反。通过对比可知,岩溶洞穴环境由于缺乏光照,空气流动缓慢,生物活动不频繁,使水体中的HCHs不易降解,沉积物中的HCHs不易重新释放而浓度高于洞外。枯水期由于洞内流速较小且变幅不大,水体中的DDTs大量沉积因而其浓度低于洞口,而丰水期洞口因受大量雨水的稀释作用DDTs反而低于洞内的含量;洞内沉积物中的DDTs则因洞内环境恒定不易重新释放和枯水期水体中的大量沉积而一直高于洞外。洞穴环境、不同污水汇入对水体中DDTs和表层沉积物中DDTs、HCHs的组成结构均有不同程度的影响,而对水体中HCHs的组成结构影响不大。此外,地下河不同部位污染源的输入对有机氯污染物的组成结构也有影响。与国内外水体及表层沉积物中HCHs、DDTs相比较,研究区水体、表层沉积物中HCHs、DDTs浓度分别处于中等和偏高水平。 相似文献
6.
沈阳市细河周边农田土壤和大气中有机氯农药和多氯联苯初步研究 总被引:2,自引:1,他引:1
在2010年5月调查了沈阳市细河沿岸表层土壤中有机氯农药(OCPs)和多氯联苯(PCBs)的污染现状,评价土壤中OCPs残留的生态风险。沈阳细河沿岸表层土壤中HCHs浓度范围分别为2.32~15.90 ng/g,平均浓度为8.99ng/g。DDTs浓度范围分别为9.06~111.6 ng/g,平均浓度为37.08 ng/g。7种PCBs异构体总平均浓度为1.01ng/g,大部分采样点OCPs和PCBs未超过国家土壤环境质量标准,推断近期可能有林丹的使用但没有新的DDTs污染源输入,但个别地点土壤中的DDTs残留浓度对生态系统健康构成了潜在的威胁。大气蒸汽态HCHs浓度为18.97 ng/m3;DDTs浓度为42.27 ng/m3;PCBs浓度为20.59 ng/m3。研究表明大气长距离传输对该区域的OCPs污染也有较为明显的影响。初步运用逸度概念模型进行分析,发现HCHs和DDTs的逸出方向为从土壤向大气挥发。 相似文献
7.
表层岩溶带土壤中有机氯农药的分布及来源特征研究——以重庆南川区为例 总被引:1,自引:1,他引:0
为了研究有机氯农药(OCPs)在表层岩溶带土壤中的分布趋势、组成特征和来源,采用气相色谱-微池电子捕获检测器(GC-μECD)分析了重庆市南川区水房泉、后沟泉、柏树湾泉、兰花沟泉等典型表层带岩溶泉上覆土层中有机氯农药的浓度。结果显示,总体上表层岩溶带土壤中的OCPs的浓度范围是7.13~323.37ng/g,其中后沟泉、柏树湾泉、兰花沟泉表层土壤中的17种OCPs检出率为100%,水房泉土壤中除p,p'-DDD外其余全部检出,但不同种类有机氯含量差异较大。其中HCHs、DDTs、CHLs、灭蚁灵是主要检出物。研究区内土壤样品中的HCHs来源于工业品HCHs和林丹使用的残留,且由于环境影响,土壤中HCH的同系物组成发生了明显变化。水房泉和柏树湾泉土壤中的DDTs来自于工业DDTs和三氯杀螨醇的混合源,而后沟泉和兰花沟泉土壤中的DDTs可能来自于工业DDTs的使用,而非三氯杀螨醇类型的DDT。对比中国和荷兰的土壤质量标准,柏树湾泉土壤中DDTs浓度接近于荷兰无污染土壤的参考值,兰花沟泉土壤中的DDTs应属于轻度污染,后沟泉土壤中的DDTs和氯丹类化合物污染程度较重,而水房泉土壤为无污染土壤。 相似文献
8.
针对长三角地区长期工业化对农业生态环境构成较大风险,本文利用气相色谱法对该地区不同利用类型土壤中22种有机氯农药进行测定,研究了有机氯农药的残留状况及其在4条土壤垂向剖面中的分布特征。结果表明,不同利用类型表层土壤中有机氯农药残留平均值为工业园区菜地(139.87 ng/g)工业园区荒地(103.1 ng/g)农业区传统菜地(26.27 ng/g)农业区水稻田(2.50 ng/g)。表层土壤中DDTs和HCHs是主要污染物,DDTs含量为0.14~485.73 ng/g(均值44.43 ng/g),HCHs含量为0.69~66.69 ng/g(均值7.73 ng/g),(DDD+DDE)/DDTs值表明该地区近期外源DDTs输入较少。土壤剖面样品分析表明,DDTs和HCHs的含量均随土壤深度增加而迅速降低,这与剖面土壤包气带岩性均以黏土和亚黏土为主,削弱了地表径流对有机氯农药的垂直迁移动力有关。本研究可为控制和改善该地区污染状况提供相关数据。 相似文献
9.
利用GC-ECD定量测定了沈阳郊区21个表层土壤样品中有机氯农药(OCPs)的含量,并对其残留特征、可能来源及生态风险进行了分析。结果表明,研究区表层土壤中OCPs的检出率达到95.2%,残留量最高值达到111.67 ng·g-1,平均值26.91 ng·g-1,其中以六六六(HCHs)和滴滴涕(DDTs)为主。与国内其他城市土壤中OCPs含量相比,沈阳郊区表层土壤HCHs和DDTs残留属于较低水平,但HCB残留属于较高水平。研究区OCPs的来源解析表明OCPs主要来自环境中的早期残留和近期林丹的使用,六氯苯(HCB)的来源还应包括工业生产。相关性分析说明土壤中总有机碳和水溶盐含量是影响OCPs残留的重要因素。生态风险评价显示表层土壤中DDTs类有机氯农药对该区生物可能仍存在生态风险。 相似文献
10.
山东烟台地区苹果果园土壤中DDTs和HCHs残留分布特征与来源解析 总被引:1,自引:1,他引:0
为研究不同土壤类型中有机氯农药的残留特征、降解程度和来源途径,采集了山东烟台9个不同地质单元苹果园根系土壤和剖面土壤样品,用电子捕获检测器气相色谱法测定其中的滴滴涕(DDTs)和六六六(HCHs)。结果表明,研究区所有类型根系土壤中DDTs和HCHs均未超出《土壤环境质量标准》的二级土壤限值(500 ng/g);土壤中DDTs的残留量及检出率均高于HCHs,DDTs检出率为100%,平均残留量为71.7ng/g,而HCHs的检出率为19.70%,平均残留量为7.9 ng/g;根系土壤中DDTs各异构体平均浓度依次为p,p’-DDT>p,p’-DDE>o,p’-DDT>p,p’-DDD,而HCHs大部分以α-HCH形式存在,部分以β-HCH、γ-HCH存在。不同类型土壤中有机氯农药残留分布特征明显不同:DDTs在棕壤土(臧家庄)中最高(145.5 ng/g),在中粗粒砂土(武宁)中最低(24.1 ng/g);而HCHs在细砂质壤土(蛇窝泊)中最高(27.9ng/g)。各剖面土壤DDTs均在<20 cm层位中残留最高。DDTs和HCHs来源解析表明:研究区土壤为好氧条件;麻砂棕壤(官道和桃村)、黏细壤土(牟平)、细砂质壤土(蛇窝泊)和棕壤土(臧家庄)近年来仍有新的DDTs输入;大部分根系土壤均未发现HCHs新来源,但麻砂棕壤(桃村)在HCHs禁用后可能仍存在林丹的使用。 相似文献
11.
Surface soil samples were collected in two karst Tiankengs, Dashiwei and Datuo, situated within the Dashiwei Tiankeng group, located in Leye County of Guangxi province, South China. The soil samples were analyzed for 23 kinds of organochlorine pesticides (OCPs) using a gas chromatography electron capture detector device. The results showed that the concentrations of OCPs in soils of Dashiwei Tiankeng ranged from 0.03 to 5.13 ng/g for total OCPs, not detectable (ND) to 0.22 ng/g for Hexachlorocyclohexane (HCHs), and 0.01 to 3.61 ng/g for Dichlorodiphenyltrichloroethane and metabolites (DDTs). Concentration of the total OCPs in soils of Datuo Tiankeng ranged from 0.13 to 14.36 ng/g, ND to 0.39 ng/g for HCHs, and 0.01 to 3.28 ng/g for DDTs. These concentrations indicated that there could be new inputs of HCHs and DDTs from recent application of lindane and dicofol in this area. Further analysis also revealed that the concentration of OCPs at the bottom of both Tiankengs was higher than the top. The variability in concentrations between the top and the bottom was attributed to the “cold trapping effect” for persistent organic pollutants (POPs) in karst Tiankeng topography. The difference in temperature between the top and bottom of Tiankeng is a predominating factor which can cause a POPs “cold trapping effect.” Other environmental factors are proposed to explain the difference in concentration such as humidity, topography (or slope), wind speed, wind direction, solar radiation, vegetation cover, and soil organic matter. The environmental condition of Dashiwei Tiankeng appears to favor the accumulation of OCPs than that of Datuo Tiankeng because Dashiwei Tiankeng is a matured Tiankeng but Datuo Tiankeng is a degraded one. Thus, there is the need for further studies on the environmental factors influencing distribution of OCPs in karst Tiankeng. 相似文献
12.
Distribution and potential sources of organochlorine pesticides in the karst soils of a tiankeng in southwest China 总被引:1,自引:0,他引:1
Yinghui Wang Yiyin Xu Shihua Qi Xiaoming Li Xiangsheng Kong Daoxian Yuan Oramah I. Theodore 《Environmental Earth Sciences》2013,70(6):2873-2881
This research was conducted in an attempt to assess the concentration levels and potential sources of organochlorine pesticides (OCPs) in the karst soils of Dashiwei tiankeng, southwest China. The tiankeng is a karst surface expression that can act as a focal point for introduction of contaminants to groundwater system, which may serve as condenser and receiver for semi-volatile persistent organic pollutants such as OCPs. In this study, surface soil samples from Dashiwei tiankeng were collected and 23 organochlorine pesticide compounds were analyzed. The results showed that the concentration was 0.019–3.605 ng/g for DDTs (sum of p,p’-DDD, p,p’-DDE, o,p’-DDT, p,p’-DDT), 0.001–0.218 ng/g for HCHs (sum of α-, β-, γ-, δ-HCH), 0.003–0.290 ng/g for CHLs (sum of heptachlor, heptachlor epoxide, TC, CC and trans-nonachlor), 0.001–0.064 ng/g for endosulfan (sum of α-endosulfan and β-endosulfan), 0.008–1.630 ng/g for HCB and 0.023–0.928 ng/g for other OCPs (sum of aldrin, dieldrin, methoxychlor, endrin, endrin aldehyde and endrin ketone). The total OCPs concentrations varied from 0.055 to 5.216 ng/g. The ratio of DDT/(DDE + DDD) in the floor soils of Dashiwei tiankeng ranged from 0.434 to 0.797, suggesting a mostly historical residue of technical DDT contamination. However, the ratio of DDT/(DDE + DDD) in the upper rim soils was higher than one, which that there was fresh DDT application nearby. Both the floor and upper rim soils of Dashiwei tiankeng had high ratios of o,p’-DDT/p,p’-DDT (range of 0.016–10.833 with mean of 5.424 and 4.667–7.714 with mean of 5.723, respectively), which implied that the primary source of DDTs was probably from dicofol-type DDT products. The average ratios of α-/γ-HCH were 24.435 in the floor soils and 1.067 in the upper rim soils, together with the averaged percentages of β-HCH among the total HCH isomers (accounting for 33.772 %), indicating that the HCHs were a dominant contribution from technical HCH usage in the past. 相似文献
13.
广州市海珠区有机氯农药污染状况及其土-气交换 总被引:5,自引:3,他引:2
通过在冬夏两季对广州市海珠区表层土壤和空气样品中有机氯农药的采样和分析,对有机氯农药残留现状和潜在生态风险进行了研究。结果表明,土壤中六六六类(HCHs)含量水平在2007年冬季和2008年夏季分别为0.57~8.77 ng/g和0.30~14.9 ng/g,平均值分别为2.87 ng/g和3.04 ng/g,都未超过国家土壤环境质量标准的一级自然背景值。冬季和夏季滴滴涕类(DDTs)含量水平分别为3.69~697.7 ng/g和0.88~263.3 ng/g,平均值分别为85.5 ng/g和39.4 ng/g。海珠区部分地点DDTs超过国家土壤环境质量标准的一级自然背景值。DDTs为该区域表层土壤中主要的有机氯农药残留。在研究区域对逸度模型进行了初步应用。 相似文献
14.
The concentrations of typical organochlorine pesticides (OCPs) (DDTs, HCHs, PCP-Na, and HCB) were measured to understand distribution and source of OCPs in surface and columnar sediments of Poyang Lake in 2006. And OCPS concentrations in surface sediment in 2017 were made a comparison with those in 2006 at several same sampling sites. OCPs showed higher concentrations in main stream than in river mouths (entrance of river flow into lake) of the lake. The average concentrations of HCHs and DDTs were 4.63 ± 3.86 and 20.15 ± 26.86 ng/g in surface sediments in 2006, respectively. Concentrations of OCPs in 2017 were lower than in 2006, such as HCHs average 1.98 ± 2.04 ng/g and DDTs average 4.87 ± 1.48 ng/g in 2017, indicating historical residual and degradation. The primary isomers of HCHs and DDTs in the lake were α-HCH, γ-HCH and p,p′-DDD, respectively. HCHs were from historical residual and lindane application. DDTs were from historical residual. PCP-Na total concentrations in surface sediment were 77.36 ng/g in 2006 and 44.04 ng/g in 2017. The concentration of HCB residues in surface sediment was 0.92 ± 0.90 ng/g in 2006 and 0.42 ± 0.38 ng/g in 2017. The concentrations of OCPs in columnar sediments showed annual variations, and the peak concentrations occurred in 1953, 1961, 1974, 1982, and 1995, showing close relations with onset of production OCPs pesticide in 1950s and its later prohibition in 1980s and a large number agricultural cultivated land decrease in 1990s in China. The concentrations of HCB in columnar sediments were average 2.33 ± 1.26 ng/g. OCPs of columnar sediments were from historical residues and lindane input. The main contamination of OCPs was PCP-Na and p,p′-DDD in Poyang Lake. On the whole, the combination of surface samples (0–5 cm in depth) and columnar samples (0–38 cm in depth) in a single study would give insight into OCPs pollution levels in different years (temporal resolution) and in different regions (spatial resolution) in Poyang Lake. 相似文献