三峡库区水体和底泥中多环芳烃和邻苯二甲酸酯类分布和来源

通过对2016年三峡库区干支流18个采样点水体和底泥中16种多环芳烃(PAHs)和6种邻苯二甲酸酯类(PAEs)污染物浓度的时空分布特征和来源进行分析,得出如下结论:三峡库区2016年水体和底泥中ΣPAHs分别为3.9~107.6 ng/L(均值为39.9 ng/L)和267.9~1018.1 ng/g(均值为490.9 ng/g),ΣPAEs分别为122.4~2884.7 ng/L(均值为848.1 ng/L)和192.9~3473.4 ng/g(均值为1253.35 ng/g).水库水体和底泥中PAHs和PAEs均表现出显著的时空分布特征.干支流水体ΣPAHs平均浓度均为放水期(6月)高于蓄水期(12月),干流底泥ΣPAHs平均含量在蓄水期高于放水期.干流水体中ΣPAEs平均浓度在蓄水期显著高于放水期,底泥中ΣPAEs平均含量为放水期高于蓄水期.库区水体中的PAHs以2~3环和4环为主,底泥中以4环和5~6环为主.水体和底泥中PAEs均以邻苯二甲酸(2-乙基已基)酯和邻苯二甲酸二正丁酯为主.库区水体中PAHs的主要来源为焦化或煤焦油挥发、石油源及燃料的中低温燃烧;底泥中PAHs主要来源为煤和生物质燃烧以及石油.水体和底泥中的PAEs主要来源于塑料和重化工工业以及生活垃圾.     

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.     

持久性有机污染物在中国湖库水体中的污染现状及分布特征

持久性有机污染物(POPs)在环境中广泛且持久存在,多数具有致畸、致癌、致突变等危害中国是全球湖泊密度较大的国家之一,湖泊在供水、渔业、维护生态系统多样性等众多方面发挥了重要作用湖泊是POPs的重要归宿之一湖泊水体中的POPs可被水生生物吸收利用并传递,对生态系统及人体健康构成较大危害因此湖泊水体中POPs的分布水平对周围的生态系统及人体健康有非常重要的影响本文收集、分析了2003年至2019年2月公开发表的80篇文献中的中国湖泊水体POPs数据,包括多环芳烃(PAHs)、六六六类农药(HCHs)、滴滴涕类农药(DDX)、多氯联苯(PCBs)、多溴联苯醚(PBDEs)、多氯联苯醚类(PCDEs)、全氟化合物(PFCs)及邻苯二甲酸酯类(PAEs),发现:目前中国已有水体POPs研究数据的湖泊共有49个,涉及19个省、直辖市、自治区,研究区域主要在东部地区(n=32),云贵高原(n=14)和青藏新疆湖区(n=3)少有研究,其它地区鲜有研究; PAHs、HCHs和DDX是研究最多的三类POPs,在中国湖泊水体中平均浓度分别为360.0±433.8 ng/L(n=26)、12.8±23.5 ng/L(n=30)、12.8±24.6 ng/L(n=24);不同湖区间、不同种类POPs以及不同时间相同POPs检出值差距均较大,东部湖区水体POPs浓度高于其它湖区;从时间角度看,虽然这三类POPs各自占总污染物量比例在2010年前后无较大变化,但2010年后的浓度与2010年以前相比有所下降,说明中国履行《关于持久性有机污染物(POPs)的斯德哥尔摩公约》内容以及对PAHs的管控减排已显成效; POPs在中国湖泊水体中的浓度与季节、水体深度(上覆水与间隙水)、采样点位置(入湖口、湖心及出水口)以及人为活动(农业耕作、生活排污、工业污水及码头船只往来等)存在一定关系,但并非完全受这些因素影响,还与POPs种类、所处区域的地理位置等诸多因素有关本文基于大量已发表文献中的研究数据,揭示了中国湖泊水体POPs的污染现状及分布特征,可为中国POPs的污染控制及湖泊保护提供一定的科学依据.     

鲫(Carassius auratus)对浅水湖泊水体浊度、营养水平和浮游生物生物量的影响——基于中宇宙模拟实验

鲫(Carassius auratus)是我国各类淡水水体的优势鱼类之一.作为底栖杂食性鱼类,一方面,鲫可以通过排泄和扰动沉积物影响湖泊营养和光照水平,通过"上行效应"促进浮游植物生长;另一方面,鲫也可以捕食浮游动物,通过"下行控制"影响藻类生长以及营养盐循环.对于浅水湖泊,两种途径对于生态系统影响的相对重要性仍有待研究.本研究设计了一个两因素户外中宇宙实验,通过在沉积物表面添加隔网的方式,比较两种情况下(能、否接触沉积物),鲫对水体浊度、营养盐和浮游生物生物量的影响.实验在16个大型钢化玻璃桶(400 L)中进行,持续36 d(2019年8月6日—9月11日).研究结果表明:1)在能接触沉积物的条件下,鲫显著促进了沉积物再悬浮,表现为水体的总悬浮物(TSS)和无机悬浮物(ISS)浓度大幅升高;水体的光衰减系数(Kd)增加,总氮(TN)和总磷(TP)浓度明显升高; 2)在不能接触沉积物的条件下,鲫对水体悬浮物(TSS和ISS)浓度和Kd的影响不明显,但是显著降低了水体TN和TP浓度; 3)在两种情况下,鲫对浮游植物叶绿素a浓度以及浮游动物生物量的影响均不显著.本研究表明鲫只有在能够接触沉积物的条件下,才会显著提高水体浊度和营养水平.因此,在缺乏沉水植被的浅水湖泊中,鲫扰动沉积物产生的"上行效应"可能是其对生态系统产生负面影响的主要途径.     

过坝下泄水流中温室气体排放速率的数值模拟

当水流通过泄洪建筑物下泄时,水体中所溶解的温室气体(二氧化碳(CO2)、甲烷(CH4)等)会因为所受压力的瞬间改变而导致溶解度降低,从而造成气液之间传质的发生及水中温室气体的排放.然而,目前对于泄流条件下水中温室气体排放的研究还较为缺乏.鉴于原型观测与模型试验的局限性,本文建立了大坝泄流条件下温室气体排放速率的数学模型...     

三峡水库近坝段水面漂浮物对水质的影响

每年汛期与蓄水期三峡水库近坝段水域会有大量漂浮物聚集,为探索三峡水库近坝段水域(坝前及以上约12.7km长的河段)水面漂浮物对水质的影响,2018年开展了漂浮物覆盖水体水质跟踪监测和漂浮物浸泡试验,并以20142018年的漂浮物产量和近坝段水域水质监测数据为基础进行了相关分析与回归分析.结果表明:漂浮物会提高坝前覆盖水体的氮类营养盐水平和有机污染物浓度,引起河湾漂浮物覆盖水域氨氮(NH3-N)浓度升高,致使氮类营养盐组成的变化和由于高锰酸盐指数/总有机碳比值(COD_(Mn)/TOC)的差异变化对水体产生有机污染.除NH_3-N外,坝前水域受漂浮物影响程度大于河湾区域,漂浮物对河湾水质的影响在蓄水期更为明显,漂浮物覆盖水体垂直方向上2 m内水质因子无明显分层现象;相比综合类漂浮物,植物类漂浮物对水质的影响更迅速和明显;漂浮物仅在其覆盖的水体小范围内对氮类营养盐指标造成影响,漂浮物产量的增加会增大近坝段水域水体悬浮物、有机污染物和还原性无机物质(COD_(Mn))浓度,形成一定的影响规律.因此,合理布置清漂作业点,高效及时地开展漂浮物清理工作,短期内优先打捞植物类漂浮物,合理实施水库调度以减少漂浮物聚集量与缩短滞留时长,加强漂浮物影响水体的水质监测对近坝区河段水环境保护意义重大.     

乌兹别克斯坦阿姆河流域水体中多环芳烃的分布、来源及风险评估

为研究乌兹别克斯坦境内阿姆河地区水体中多环芳烃（PAHs）污染特征、来源并进行风险评估,采用高效液相色谱二极管阵列检测器串联荧光检测器法,对研究区域50个采样点中16种优先控制的多环芳烃进行了检测分析.结果表明,阿姆河地区水体中多环芳烃总浓度范围为3.19~779 ng/L,平均值为98.4 ng/L,中位值为40.1 ng/L,单体浓度范围为0~333 ng/L,检出浓度最高的单体为苊烯,5种单体芴、蒽、荧蒽、芘和的检出率为100%,单体苯并[b]荧蒽的检出总量最高,水样中总浓度为786 ng/L,平均值为15.7 ng/L,中值为2.79 ng/L.不同水体含中低环多环芳烃（2~4环）与高环多环芳烃（5~6环）总浓度相近,但不同采样点间浓度差异较大.浓度较高的采样点主要集中在阿姆河三角洲的城市、农业灌溉区及近咸海区域.与世界不同研究区域相比,阿姆河流域多环芳烃浓度处于中等水平.采用相对丰度法、同分异构体比值法及正定矩阵分解法相结合进行源解析,表明研究区域水体中多环芳烃多为混合来源,其中阿姆河下游河段水体多环芳烃主要来源于生物质燃烧,而阿姆河三角洲区域主要来源于生物质燃烧、石油、天燃气燃烧及汽车尾气排放.生态风险评估结果显示,研究区水体单体多环芳烃中萘、苊、菲和蒽的生态风险较低,其余单体处于中等风险等级,其中苯并[b]荧蒽的污染程度较为严重;总体上阿姆河流域ΣPAHs风险等级相对较低,但仍有12和8个点位分别处于中等风险2和高风险等级,且主要集中在阿姆河三角洲地区,需采取相应措施加以控制.     

两种氮浓度对轮叶黑藻(Hydrilla verticillata)腐解过程营养盐释放及附着生物膜内氮循环基因丰度的影响

氨氮是地表水常见污染物,尤其在农业区域,氮类化肥的不合理施用会导致周边水体氮浓度迅速升高并保持较高水平.然而,当前对高氮水平下沉水植物腐败和附着氮循环微生物的影响尚不清楚.以轮叶黑藻(Hydrilla verticillata)为研究用沉水植物,在实验室内模拟水体内8和16 mg/L氮浓度下轮叶黑藻腐解过程中营养盐释放及残体表面微生物氮循环功能基因丰度的变化.研究发现水体两种氮浓度下轮叶黑藻腐解过程中残体腐解及营养盐释放速率无显著差异;与对照相比,植物腐败初期水体内碳、磷浓度迅速增加,而溶解氧浓度及氧化还原电位迅速降低,随着时间的推移上述水质指标逐步恢复至初期状态(第146天);水体荧光溶解性有机质主要包括紫外类富里酸、可见类富里酸、色氨酸类蛋白质和酪氨酸类蛋白质等类型.在5个氮循环相关基因中,氮负荷增加对轮叶黑藻残体生物膜内amo A、napA和narG的丰度有显著影响.冗余分析表明氮循环基因丰度受水体总氮浓度的影响较小,与植物总有机碳含量和水体化学需氧量及溶解氧浓度存在相关性.研究结果表明虽然当前氮水平对植物腐败过程影响不大、对氮循环基因丰度有一定影响,但是对该水生植被(尤其是植物腐败初期)和农业退水排放的管理仍需加强,以降低其对水体的影响.     

湿地植物种类和生长方式对根际酞酸酯及其单酯代谢物分布特征的影响

选取天津大学校内两个相邻的小型湖泊(青年湖和爱晚湖)为研究对象,研究了湿地植物种类(芦苇和香蒲)和生长方式(单生和混生)对根际酞酸酯(PAEs)及其单酯代谢物(PAMs)分布特征的影响.结果显示:几乎所有的样品中都能检测到酞酸丁二酯(DBP)和酞酸二异辛酯(DEHP)及其单酯代谢物(MBP和MEHP),并且DBP和DEHP的浓度比相应的单酯代谢物高1～2个数量级;沉积物和根样品中DEHP的浓度高于DBP;芦苇和香蒲根对DEHP的富集系数(RCF)大于DBP.当芦苇和香蒲单生时(即青年湖),芦苇根际沉积物中DBP和DEHP浓度≤香蒲根际沉积物的浓度,并且芦苇根的RCF值也小于香蒲.当芦苇和香蒲混生时(即爱晚湖),芦苇根际沉积物中DBP和DEHP浓度<香蒲根际沉积物的浓度,而芦苇根的RCF值≥香蒲根的RCF值,与青年湖中不同.青年湖香蒲根际沉积物中DBP和DEHP的浓度小于爱晚湖,而香蒲根的RCF值与此刚好相反.芦苇根对这两种PAEs的富集没有这种关系,可能是由于这两个湖中芦苇的生长状况不同,与香蒲混生时,芦苇的生长受到抑制.对PAEs的单酯代谢产物分析发现,沉积物中MBP/DBP>MEHP/DEHP.MEHP在根中的浓度多数情况高于MBP,表明MEHP比MBP具有较强的根富集能力.同种植物单生时,根中PAM浓度均≥混生.     

秀丽白虾(Exopalaemon modestus)对亚热带湖库春夏季水体营养水平和浮游生物群落的影响——基于微宇宙模拟实验

秀丽白虾(Exopalaemon modestus)是我国大型淡水湖库的重要经济渔获对象,也是水体中浮游动物的捕食者之一.以往的研究从渔业的角度揭示了秀丽白虾的生物学特征与食性,但少有研究探讨秀丽白虾这一无脊椎动物捕食者对春、夏季浮游生物群落的影响.本研究设计了一个单因素户外微宇宙实验,比较了春季—初夏(4-6月)时期,有无秀丽白虾条件下水体氮、磷浓度以及浮游生物生物量和群落结构的变化.结果 表明:1)秀丽白虾的存在显著降低了春季水体总氮(TN)浓度,增加了水体总磷(TP)浓度,降低了水体TN∶TP比值;2)秀丽白虾的捕食减少了大型枝角类Daphnia pulex和浮游动物总生物量,D.pulex在浮游动物群落中的优势度被轮虫取代,浮游动物群落趋于小型化;3)秀丽白虾显著增加了春季水体叶绿素a浓度,但对浮游植物群落结构的影响不明显.研究表明在大型湖库中,秀丽白虾等无脊椎动物捕食者可能是影响浮游生物群落变化的因素之一,在春季浮游生物研究中应予以关注.     

The Consequences of the Oder Flood in 1997 on the Distribution of Polycyclic Aromatic Hydrocarbons (PAHs) in the Oder River Estuary

Changes in the levels and spatial distribution of polycyclic aromatic hydrocarbons (PAHs) as a consequence of the Oder flood in the summer of 1997 were investigated in surface water samples and fluffy layer material from the Oder Lagoon and the Pomeranian Bight. The measurements of the contaminants were complemented by satellite data to describe the spreading of the Oder flood discharge including the distribution of the particulate material. During the flood elevated levels of PAHs were discussed in the surface water and fluffy layer material of the Oder River Estuary in comparison to the average values in this region. These increased concentrations were attributed to flooding of municipal and industrial waste disposal areas in the drainage area of the Oder River. The meteorological conditions during the sampling period were characterized by predominant easterly winds, which guided the river plume along the German coast into the Arkona Sea, as verified by satellite observations. The highest concentrations of PAHs were observed near the mouth of the Swina and along the main direction of the river plume. Elevated concentrations of PAHs were also found in fluffy layer samples taken from the Oder Lagoon in late August. As derived from satellite data the eastern and the western parts of the lagoon differed in their SPM load during the entire flood period. The eastern part was covered by Oder water, while the western part contained a mixture of Oder Lagoon water. The highest concentrations of PAHs were not observed in the western part with the highest suspended matter values, but in the eastern part where the flood water entered the lagoon. Despite the significantly increased PAH levels measured during the flood, all measured concentrations were below the values that are considered to pose a risk to the ecosystem.     

Amplification of flood discharge caused by the cascading failure of landslide dams

The cascading failure of multiple landslide dams can trigger a larger peak flood discharge than that caused by a single dam failure.Therefore,for an accurate numerical simulation,it is essential to elucidate the primary factors affecting the peak discharge of the flood caused by a cascading failure,which is the purpose of the current study.First,flume experiments were done on the cascading failure of two landslide dams under different upstream dam heights,downstream dam heights,and initial downstream reservoir water volumes.Then,the experimental results were reproduced using a numerical simulation model representing landslide dam erosion resulting from overtopping flow.Finally,the factors influencing the peak flood discharge caused by the cascading failure were analyzed using the numerical simulation model.Experimental results indicated that the inflow discharge into the downstream dam at the time when the downstream dam height began to rapidly erode was the main factor responsible for a cascading failure generating a larger peak flood discharge than that generated by a single dam failure.Furthermore,the results of a sensitivity analysis suggested that the upstream and downstream dam heights,initial water volume in the reservoir of the downstream dam,upstream and downstream dam crest lengths,and distance between two dams were among the most important factors in predicting the flood discharge caused by the cascading failure of multiple landslide dams.     

三峡大坝上下游水质时空变化特征

为探索三峡大坝上下游（坝上99.9 km、坝下63.0 km、全长162.9 km）水质时空变化特征,运用主成分分析和方差分析对2016年近坝段水质时空变化特征进行了分析.主成分分析表明,水文因子流量（Q）、气温（T）、水位（Z）和水质因子（水温（WT）、pH、电导率（EC）、溶解氧（DO）、悬浮物（SS）、高锰酸盐指数（COD_Mn）、硫酸盐（SO₄^2-）、氟化物（F^-）、总硬度（T-Hard）、硝态氮（NO₃^--N）、总氮（TN）和硒（Se））的变化主导着研究区域水质变化;各采样点主成分得分和双因素方差分析结果显示研究区域水质因子时间变化主要呈现出季节和不同水库运行时期的差异.消落期（2-5月）,T-Hard、F^-、SO₄^2-和EC是影响河流水质变化的主导因子;汛期（7-8月）,Q、SS、COD_Mn、NO₃^--N、TN和Se是影响河流水质变化的主导因子;T和WT主导着汛末（9月）河流水质变化,并引起了DO等理化特性的变化;高水位运行期（12月）,Cl^-是影响河流水质变化的主导因子.现阶段,DO、有机污染物（COD_Mn）、无机盐（SO₄^2-和F^-）、营养盐类（NO₃^--N和TN）、类金属元素（Se）和水体的矿化程度（T-Hard）的变化主导着区域水质的变化,是三峡大坝近坝段水域水质的控制因子.方差分析表明,河流的理化特性（DO、pH和SS）、营养盐组分构成（NH₃-N和NO₃^--N）、无机盐类（EC和Cl^-）、石油类有机污染物及粪大肠菌群（FC）等指标在坝上与坝下断面存在显著性差异.气温、水温、降雨、含沙量的季节性影响因素和水库调度运行模式是影响近坝段水质时间差异的主要因子;空间差异主要受城区污染排放和三峡水库调度引起的坝上和坝下水文和水动力学条件差异影响.因此控制研究区域因人类活动等造成的外源性污染,并针对不同类污染物质的季节变化特征实施合理的水库运行方式是近坝段水质提升的关键.     

Enhanced hysteresis of suspended sediment transport in response to upstream damming: An example of the middle Yangtze River downstream of the Three Gorges Dam

The peak in sediment transport in alluvial rivers generally lags behind the peak in discharge. It is thus not clear how the hysteresis in the sediment/discharge relationship may be impacted by damming, which can fundamentally alter the water and sediment regimes in the downstream reaches of the river. In this study, a total of 500 flood events in the Yichang–Chenglingji Reach (YCR) of the Middle Yangtze River immediately downstream of the Three Gorges Dam (TGD) are analysed to study the impacts of dam operations on the hysteresis of suspended sediment transport. Sediment rating curves, hysteresis patterns, as well as lag times, are investigated to determine the relationship between suspended sediment concentration (SSC) and flow discharge (Q) at different temporal scales, from inter-annual to individual flood events, for the pre- and post-TGD period from 1992 to 2002 and from 2003 to 2017, respectively. The results showed that the TGD operation decreased the frequency and magnitude of floods. The decrease in peak flow and increase in base flow weakened the flood contribution to the annual discharge by nearly 20%. However, the relative suspended sediment load contribution during flood events was much higher than the discharge contribution, and was little impacted by the dam. At seasonal and monthly scales, more than 80% of the suspended sediment was transported by ~65% of the water discharge in the summer and early autumn. The monthly SSC–Q relationship changed from a figure-eight to an anti-clockwise pattern after the construction of the TGD. For single flood events, the TGD operations significantly modified the downstream SSC–Q hysteresis patterns, increasing the frequency of anti-clockwise loops and the lag time between peak Q and peak SSC. These adjustments were mainly caused by differences in the propagation velocities of flood and sediment waves and the sediment ‘storage–mobilization–depletion’ process, whereas the influence of lateral diversions was small. © 2020 John Wiley & Sons, Ltd.     

丹江口水库叶绿素a浓度的时空特征及影响因子分析

2017年5月—2019年10月,对"南水北调"中线水源水库——丹江口水库库区水体7个监测位点、0～20 m间4个水层的垂向叶绿素a (Chl.a)浓度与水质因子进行了季度性调查,以期了解不同位点、不同水层Chl.a分布的主要驱动因子.结果表明,丹江口水库各位点营养状态指数(TSI)均为中营养化状态.水体Chl.a浓度具有逐年增加的趋势,且极高值有逐渐增加的趋势.营养盐和Chl.a浓度均存在较大的空间异质性,入库区具有较高的总磷和氨氮浓度,汉江库区具有最高的Chl.a浓度,源头污染源控制和监测仍然是丹江口水库管理的重中之重.不同位点Chl.a浓度的驱动因子存在较大差异,汉江入库和大坝区Chl.a浓度分别受到硝态氮和p H的影响,而出水口大坝位点主要受到了水深、水温和氨氮的影响.丹江入库区Chl.a浓度受到了水深、氨氮、总磷和水温的影响,但丹江库区表现出了与其他生态区较大的区别,其Chl.a浓度主要受到水深和有机质输入的影响.因此,对丹江口水库各位点的管理,应该分不同生态区采取针对性的管理措施.本研究旨在为南水北调中线工程可持续的生态调度提供基础生态数据支持,为完善水库水源地的有效管理提供理论支撑.     

Multi-residues of organic pollutants in surface sediments from littoral areas of the Yellow Sea, China

Concentrations of all studied organic pollutants, except for DDTs, were greatest at sites in Dalian Bay, where surface sediment concentrations of PHCs, PAHs, PCBs and DDTs exceeded the corresponding ERL values. The sum concentration of DDTs was greatest in Haizhou Bay exceeding the related ERM value. In terms of compositions of PAHs and PAEs, the predominant components were the MMW and HMW compounds, DBP and DEHP, respectively. The main degradation product of p,p'-DDT was p,p'-DDD at most sampling sites. The principal sources of PAHs and DDTs involved various pyrolytic processes (i.e., combustion of biomass and vehicle exhaust), and application of technical DDT (in the form of impurity or raw material), and a mixture of technical DDT and technical dicofol. Moreover, the coastal site with greatest potential ecological risk from total PAHs was located in Dalian Bay, while the littoral areas of Dalian Bay, two harbor cities (Yantai-Weihai), Jiaozhou Bay, and Haizhou Bay, had relatively high potential risk from DDTs, especially in Haizhou Bay.     

Large wood distribution,mobility, and recruitment in an inter‐dam river reach: A comparison with geomorphic process on the Garrison Reach of the Missouri River pre and post the historical 2011 flood

This study assessed the effect of the largest flood since dam regulation on geomorphic and large wood (LW) trends using LW distributions at three time periods on the 150 km long Garrison Reach of the Missouri River. In 2011, a flood exceeded 4390 m³/s for a two‐week period (705% above mean flow; 500 year flood). LW was measured using high resolution satellite imagery in summer 2010 and 2012. Ancillary data including forest character, vegetation cover, lateral bank retreat, and channel capacity. Lateral bank erosion removed approximately 7400 standing trees during the flood. Other mechanisms, that could account for the other two‐thirds of the measured in‐channel LW, include overland flow through floodplains and islands. LW transport was commonly near or over 100 km as indicated by longitudinal forest and bank loss and post‐flood LW distribution. LW concentrations shift at several locations along the river, both pre‐ and post‐flood, and correspond to geomorphic river regions created by the interaction of the Garrison Dam upstream and the Oahe Dam downstream. Areas near the upstream dam experienced proportionally higher rates of bank erosion and forest loss but in‐channel LW decreased, likely due to scouring. A large amount of LW moved during this flood, the chief anchoring mechanism was not bridges or narrow channel reaches but the channel complexity of the river delta created by the downstream reservoir. Areas near the downstream dam experienced bank accretion and large amounts of LW deposition. This study confirms the results of similar work in the Reach: despite a historic flood longitudinal LW and channel trends remain the same. Dam regulation has created a geomorphic and LW pattern that is largely uninterrupted by an unprecedented dam regulation era flood. River managers may require other tools than infrequent high intensity floods to restore geomorphic and LW patterns. Copyright © 2018 John Wiley & Sons, Ltd.     

河北王快水库沉积物多环芳烃的分布、来源及生态风险评价

对王快水库沉积物中16种多环芳烃含量进行了检测,结果表明,王快水库沉积物多环芳烃含量处于中等污染水平.多环芳烃总含量由库区上游到坝前逐渐升高,多环芳烃总含量在沉积物纵向上的总体分布趋势是随着剖面深度的增加而降低,低环的萘和菲,高环的荧蒽、苯并[b]荧蒽、屈和芘是沉积物中主要的优势化合物,表层和剖面沉积物中多环芳烃的含量与有机碳含量呈正相关关系,相关系数分别为0.8154和0.9534.王快水库沉积物中多环芳烃主要来源化石燃料及生物质的燃烧,风险评价结果表明,严重的多环芳烃生态风险在王快水库沉积物中不存在,但是芴化合物含量超过了风险评价低值,可能存在着对生物的潜在危害.