千岛湖表层沉积物中有机氯农药的残留特征及生态风险评价

对千岛湖表层沉积物中21种有机氯农药(OCPs)的残留现状进行调查,明确HCHs与DDTs的组成特征及源解析,并评估其生态风险.结果表明,千岛湖表层沉积物中共检出12种OCPs,各采样点位OCPs总量的浓度范围在0.43~12.70 ng/g之间,平均值为5.28±4.84 ng/g,处于低残留水平,其中DDTs是主要的残留物,街口、大坝前点位样品出现OCPs高残留.工业DDTs的历史使用是千岛湖表层沉积物DDTs残留的主要来源,仅街口点位样品存在林丹的污染并有新的DDTs输入,应引起重视.利用沉积物质量基准法、沉积物质量标准法分别对千岛湖表层沉积物中OCPs的生态风险进行评价,结果表明部分点位样品中OCPs的残留现状对该区生物可能存在生态风险.     

巢湖悬浮物中有机氯农药的分布、来源与风险

利用GC-MS测定了2010年5月至2011年4月巢湖4个采样点悬浮物中有机氯农药(OCPs)含量,分析了悬浮物中OCPs残留水平的时空变化及其组成特征,探讨了悬浮物中主要OCPs的可能来源与生态风险.结果表明:(1)巢湖悬浮物中共检出17种OCPs,分别为六六六类(HCHs)农药的4种异构体(α-、β-、γ-、δ-HCH)、滴滴涕类(DDTs)农药的两种母体(o,p'-、p,p'-DDT)和3种代谢产物(o,p'-、p,p'-DDE,p,p'-DDD)、六氯苯、七氯、艾氏剂、异艾氏剂、氯丹的两种异构体(α-、γ-chlordane)、硫丹-I和灭蚁灵.(2)巢湖悬浮物中∑OCPs含量为172.7±434.9 ng/g,其中∑HCHs含量为15.1±10.3 ng/g,∑DDTs含量为138.8±407.3 ng/g;DDTs在夏季污染水平达到最高;空间上,污染程度为:东部湖区西部湖区中部湖区.(3)DDTs在总OCPs中占有绝对优势,DDTs比例夏季最高而秋季最低;HCHs仅在秋季为主要污染物.(4)HCHs主要来源于近期林丹的非法使用;而DDT主要来源于工业DDT的使用,在春季可能存在DDT的非法使用;悬浮物中DDT的降解环境主要为有氧环境.(5)巢湖悬浮物中p,p'-DDT和o,p'-DDT会对水生生物产生潜在的不利影响.     

白洋淀表层沉积物中有机氯农药和全多氯联苯的分布特征及风险评估

为了解白洋淀表层沉积物中有机氯农药(OCPs)和多氯联苯(PCBs)的污染情况,采用改进的GC-μECD方法对白洋淀11处沉积物进行了20种OCPs和全部209种PCB单体的定量检测和分析.结果显示:白洋淀11个沉积物样品共检出10种OCPs和24种PCBs,∑OCPs和∑PCBs的含量范围分别为1.22～52.45 ng/g(DW)和nd～37.61 ng/g,在国内处于中等水平; OCPs组成中以HCHs和Dieldrin(狄氏剂)为主,分别占到∑OCPs的39.9%和31.5%,其中7个采样点的HCHs以林丹输入为主,4个采样点以工业六六六污染为主.DDTs检出率较低,来源主要为历史残留;检出的PCB单体以低氯联苯为主,其中一氯、二氯和三氯联苯占∑PCBs的64.73%;采用沉积物质量标准法进行生态风险评估,结果表明白洋淀地区沉积物中p,p'-DDD和∑PCBs生态风险较低,Dieldrin生态风险尚需关注,γ-HCH生态风险较高,不容忽视.     

太湖表层沉积物中有机氯农药残留及遗传毒性初步研究

采用GC-ECD对太湖表层沉积物中的有机氯农药含量进行了定性定量分析.太湖20个采样点均有不同程度的有机氯农药检出,16种有机氯农药总量为4.22-460.99ng/g(dw),北部湖区、潮心区以及沿岸区等均有高值点出现,与沉积物有机质含量、氮磷营养盐含量分布并不一致.检出率最高的有机氯农药组分为DDTs、HCHs.DDTs含量检出顺序为P,P'-DDT>P,P'-DDD>P,P'-DDE,说明环境中可能仍然具有DDT箱入特征;HCHs中?HCH,?HCH检出相当,怃-HCH检出较高,主要为早期残留.结合鼠伤寒沙门氏菌/哺乳动物微粒体酶系(Ames)试验研究太湖典型溯区表层沉积物中有机污染物的遗传毒性,初步确定可能的生态风险因子.     

南太湖区域表层沉积物中有机氯化合物及重金属污染现状

对南太湖水域表层沉积物中的19种有机氯化合物及6种重金属的含量、分布及其生态风险进行了研究和评价.所测样品中有机氯农药(OCPs)和多氯联苯(PCBs)含量范围分别为0.51 -4.98、1.49-15.15ng/g(dw),与国内其它水域沉积物中OCPs、PCBs的含量相比处于较低水平.OCPs中的主要污染物是α-六...     

广东新丰江水库XFJ-1孔DDTs和HCHs的沉积记录

以~(210)Pb对广东新丰江水库XFJ-1孔进行了定年,以GC-ECD测定新丰江水库沉积钻孔中DDTs和HCHs的含量,通过对比其剖面变化特征与该类农药在我国的生产、使用历史,探讨了水库中DDT、HCH的历史输入途径.过去30年来,XFJ-1孔平均沉积速率为1.42cm/a,沉积物中HCHs和DDTs的含量分别为1.26-3.90ng/g和1.00-3.96ng/g.DDTs、HCHs含量从20世纪80年代初逐渐下降,总体上与我国1983年开始禁止DDT、HCH的大规模生产和使用这一历史事件相符.DDTs、HCHs及其化合物比值的剖面变化特征均表明:流域内后期土壤侵蚀、搬运的再循环污染物质(即二次污染源)对水库DDT和HCH的贡献不明显;相反,农药历史使用(即一次污染源)是其主要来源,大气沉降是其主要输入途径.此外,γ-HCH、o,p′-DDT和p,p′-DDT含量的垂直变化表明,大规模禁用以后这些化合物仍有少量新的输入,需引起重视.     

多环芳烃在小白洋淀挺水植物中的分布、组成及其影响因素

利用GC-MS测定了端村小白洋淀5个采样点三种主要挺水植物(荷花、蒲草和芦苇)中16种优控多环芳烃(PAHs)的含量,分析了其分布与组成特征及其影响因素。结果表明:(1)16种优控多环芳烃总量(PAH_(16))在三种挺水植物中的平均干重含量范围为82.5-448.6ng/g(dw),七种挺水植物组织荷叶、荷茎、蒲叶、蒲茎、蒲根、苇叶与苇根中PAH_(16)的平均干重含量分别为448.6ng/g(dw)、129.3ng/g(dw)、292.6ng/g(dw)、166.8ng/g(dw)、82.5ng/g(dw)、141.5ng/g(dw)和90.0ng/g(dw),这些数据表明同种植物的叶中PAHs含量最高、茎中次之、根中最低;PAHs各组份在七种挺水植物中的含量具有显著的正相关关系,反映了PAHs在植物组织中的分布模式极为相似.(2)七种挺水植物组织中,均以低环PAHs为主,中环PAHs次之,高环PAHs很低,其百分比范围分别为66.2%(荷叶)-89%(蒲茎)、10.2%(蒲茎)-32.6%(荷叶)和0.6%(蒲叶)-3.7%(苇根);菲、荧蒽、萘、芴、芘和屈6种PAHs组分在挺水植物组织中的平均百分含量较高,分别为35.3%、15.5%、12.1%、11.7%、9.2%和5.2%,占PAH_(16)的89%.3)PAHs在挺水植物中的含量与植物含脂率具有显著的正相关关系,与PAHs组分的辛醇-水分配系数(K_(ow))以及辛醇-大气分配系数(K_(oa))具有显著的负相关关系.     

巢湖表层沉积物中多环芳烃分布特征及来源

于2010年,采用野外采样调查、色谱分析与统计比较的方法,研究巢湖表层沉积物中27个采样点中多环芳烃(PAHs)分布特征及污染来源.结果表明:巢湖表层沉积物中检测出的14种优控PAHs总浓度为116.0~2832.2 ng/g(DW),平均值为898.9±791.0 ng/g(DW).多环芳烃组成主要以5~6环PAHs为主,占总量的32%~58%.沉积物中总有机碳含量与PAHs总量呈现良好相关性.利用蒽/(蒽+菲)与苯并[a]蒽/(苯并[a]蒽+屈)比值法对PAHs来源进行解析得出,巢湖表层沉积物中PAHs主要来源为燃烧源.与国内其它水体PAHs含量对比表明,巢湖沉积物中PAHs污染处于中等水平.生态风险评估得出南淝河表层沉积物中PAHs存在生态风险,其它采样点表层沉积物中PAHs生态风险均较低.     

太湖表层沉积物多环芳烃的空间分布、来源及其风险

随着太湖流域社会与经济的发展,多环芳烃(PAHs)在各种环境介质中逐渐累积,污染日益严重,可能对太湖生态环境及周边人体健康构成威胁。为探究太湖沉积物PAHs的来源及生态风险,于2021年12月在太湖采集30个表层沉积物样品,利用气相色谱-质谱联用仪(GC-MS)检测样品中16种PAHs含量;利用受体模型和苯并[a]芘(BaP)毒性当量法进行来源解析及生态风险评估,并将各来源贡献与毒性当量浓度相结合,量化源风险。结果表明,太湖表层沉积物中16种PAHs总含量介于124~592 ng/g之间,平均值为294 ng/g,中值为279 ng/g;高环多环芳烃(HMW PAHs)为主要组分,占∑PAHs的67%。高含量区域位于竺山湾、梅梁湾、贡湖湾和西太湖,与国内外其他湖泊沉积物相比,太湖沉积物PAHs含量处于较低水平。源解析的结果表明,太湖表层沉积物中PAHs交通排放源贡献率为29.1%、煤炭燃烧源贡献率为26.7%、生物质燃烧源贡献率为28.7%、石油源贡献率为15.6%。生态风险评价结果表明,交通排放源、生物质燃烧源、煤炭燃烧源和石油源的BaP毒性当量含量(TEQ_BaP)均值分别为19.34、17.81、16.33和9.1 ng/g,均小于70 ng/g,几乎处于无风险水平。西太湖、贡湖湾和梅梁湾的部分区域ΣTEQ_BaP大于70 ng/g属于潜在风险区,具有一定潜在毒性。在后续的污染治理中应重点关注太湖西北部地区污染物的排放。本研究可为沉积物中PAHs污染的研究提供数据支撑,为地方政府精准、高效地管控PAHs污染提供理论依据。     

长江中游湖泊表层沉积物多环芳烃的分布、来源特征及其生态风险评价

为明确长江中游地区湖泊沉积物中多环芳烃（PAHs）的分布特征、来源及其生态风险,于2018年7月采集了该地区12个湖泊的表层沉积物样品.采用气相色谱-质谱联用仪（GC-MS）测定了沉积物中16种PAHs的含量.结果表明：12个湖泊沉积物中均检测出16种优控PAHs,PAHs的总含量在572.7~1766.2 ng/g （dw）之间（均值为976.5±285.0 ng/g （dw））.武汉市东湖沉积物中PAHs含量最高,达到1634.8±111.4 ng/g （dw）.与国内外其他地区湖泊沉积物相比,长江中游地区湖泊沉积物中PAHs含量高于国内偏远地区的抚仙湖、青海湖及博斯腾湖,低于东部地区的巢湖、太湖及美国经济工业发达地区的湖泊.根据单体PAH的聚类分析结果,12个湖泊可以分成3种类型,类型1主要以低环为主,占比为64.04%±7.02%,类型2低环和中高环分布相对平均,分别为50.76%±5.17%和49.24%±5.17%,类型3低、中、高环分布相对平均,占比分别为35.35%±3.56%、26.17%±0.45%和38.48%±3.84%.综合该区域PAHs的分布特征及异构体比值法与主成分分析法的结果表明,类型1湖泊沉积物中PAHs主要来源为煤炭、木材等生物质的燃烧源;类型2和类型3湖泊沉积物中PAHs主要来源为煤炭、木材等生物质的低温燃烧以及机动车等燃烧汽油、柴油的尾气排放和工业炼焦等化石燃料的高温燃烧源.沉积物中PAHs与总有机碳（TOC）之间显著的相关性表明,沉积物中TOC含量是影响长江中游湖泊沉积物中PAHs归趋分布的主要因素.长江中游流域湖泊沉积物中PAHs的RQ_NCs值均小于800,且RQ_MPCs值大于1的风险商值法生态风险评价结果表明,长江中游流域湖泊表层沉积物中PAHs整体呈中等风险水平.     

A Monte Carlo study of rainfall forecasting with a stochastic model

A procedure for short-term rainfall forecasting in real-time is developed and a study of the role of sampling on forecast ability is conducted. Ground level rainfall fields are forecasted using a stochastic space-time rainfall model in state-space form. Updating of the rainfall field in real-time is accomplished using a distributed parameter Kalman filter to optimally combine measurement information and forecast model estimates. The influence of sampling density on forecast accuracy is evaluated using a series of a simulated rainfall events generated with the same stochastic rainfall model. Sampling was conducted at five different network spatial densities. The results quantify the influence of sampling network density on real-time rainfall field forecasting. Statistical analyses of the rainfall field residuals illustrate improvement in one hour lead time forecasts at higher measurement densities.     

Earthquake Engineering and Engineering Vibration Aims And Scope

正This journal is established by the Institute of Engineering Mechanics(IEM),China Earthquake Administration,to promote scientific exchange between Chinese and foreign scientists and engineers so as to improve the theory and practice of earthquake hazards mitigation,preparedness,and recovery.To accomplish this purpose,the journal aims to attract a balanced number of papers between Chinese and     

Foreword

Destructive earthquakes have caused great damage in China and the United States and collapsing buildings havecaused many deaths and injuries. The field of earthquake engineering studies earthquake hazards, the occurrence ofearthquakes of various magnitudes, the nature of the ground shaking during an earthquake, the vibration of structuresduring earthquakes, the strengthening of existing structures and the design of new structures to be earthquake resistant,and finally, how to cope with earthquake damage and restore a city to normal functioning. Such efforts are in progressin both countries, but unfortunately, the language barrier interferes with the free flow of information between China andthe Untied States. It would be mutually beneficial if some means could be developed to promote the exchangeof information across the Pacific Ocean. This new journal has been established for this purpose and its success willbe an important step in promoting earthquake engineering in China and the United States.     

WORLD ASSOCIATION FOR SEDIMENTATION AND EROSION RESEARCH(WASER)

正President:Giampaolo Di Silvio,Italy Vice Presidents:Ulrich C.E.Zanke,Germany Zhao-yin Wang,China The World Association for Sedimentation and Erosion Research(WASER),inaugurated on Oct.19,2004,is an independent non-governmental,non-profit organization.The mission of WASER is to promote international co-operation on the study     

Enhancing remote sensing research on global change to improve our understanding on Earth system processes

正Global Change includes climate change and other environmental changes caused by the joint interaction among various layers of Earth. From the positive side, global change provides new opportunities to human and other living forms on Earth. In the meantime, it creates tremendous challenges and negative impact. At present, the negative impacts have reached all primary processes of the global ecosystem and every aspect of human society, especially causing degradation of the ecosystem. For instance, intensive deforestation causes decline of biodiversity; global warming causes sea level rise and increases     

Dissolved Carbohydrate Concentration,Composition, and Bioavailability to Microbial Heterotrophs in Stream Water

Dissolved total carbohydrates (DTCH), dissolved free monosaccharides (DFMS), dissolved organic carbon (DOC), biodegradable DOC (BDOC), and humic substances (HS) were measured in White Clay Creek (WCC), a stream in southeastern Pennsylvania Piedmont, USA. Samples were collected over different seasons and under baseflow and stormflow conditions. DOC concentrations ranged from 1.0 to 12.8 mg/L C with the highest concentrations associated with stormflows. Carbohydrates ranged from 0.42 to 12.4 μM and accounted for 2.9 to 12.7% of the DOC. Humic substances represented the major DOC fraction, accounting for 55 to 72% of the DOC pool under all flow conditions. The humic fraction had a lower carbohydrate content (4.4%) than the non-humic fraction of DOC (7.2%). Stormflow DOC was enriched in carbohydrates relative to baseflow DOC, but the percentage of humic-C changed little. Carbohydrates were primarily present as dissolved polysaccharides (55%), but a significant fraction was bound to humic substances (40%), while a small proportion was present as monosaccharides (5%). The major monosaccharides in stream water, listed in order of decreasing concentration, included glucose, galactose, rhamnose, xylose, arabinose, mannose, and fucose. On average (30.6 ± 7.4)% (n = 44) of the stream water DOC was biodegradable, and carbohydrates accounted for 9.9 to 17.7% of the BDOC.