不同时空尺度下土地利用对洱海入湖河流水质的影响

土地利用与入湖河流水质的关系存在时空差异。以洱海西部入湖河流及其小流域为研究对象,综合空间分析和数理统计手段,探讨两者随空间尺度和时间变化的关系,结果表明:选取的小流域、河岸带30m缓冲区、河岸带60m缓冲区和河岸带90m缓冲区4种尺度下,对入湖河流水质影响显著的土地利用类型为建设用地和植被(包括林地和牧草地),影响最大的空间尺度为小流域尺度,河岸带30m缓冲区次之;小流域尺度下,建设用地面积百分比与入湖河流COD和TP浓度呈正相关,植被面积百分比与NH_4~+-N浓度呈负相关,响应土地利用的主要水质指标为TN和TP,回归调整系数分别为0.624和0.579;季节性关联分析表明建设用地与COD、NH_4~+-N、TP的回归关系在雨季强于旱季,植被与COD、TP的回归关系在雨季强于旱季,雨季建设用地和植被面积变化引起COD浓度变化更快。在流域管理中,针对植被覆盖率低、建设用地占比高的白鹤溪和中和溪应重点加强雨季土地利用管控,增加植被覆盖率,合理开发建设用地。     

长江上游坡地景观特征对河流水质的影响

景观组成及景观格局特征决定了污染物的来源和地表景观的拦截消纳潜力,地表坡降会加剧土壤侵蚀,坡地景观特征是影响河流水质的重要因素。研究基于长江上游重庆段2015年水质监测数据和30 m空间分辨率土地利用数据,提取河岸带100 m、200 m、300 m、500 m、1000 m和子流域6种空间尺度上景观格局和景观组成,并进一步将景观组成分为总地类、缓坡地类和陡坡地类三种不同坡度尺度,再采用相关分析和冗余分析（RDA）等方法定量探讨了坡地景观特征（坡地景观组成、景观格局）对河流水质的多时空尺度影响。结果表明：坡地景观特征对2015年长江上游重庆段河流水质的影响具有空间尺度效应;坡地景观特征对河流水质的影响在河岸带尺度强于子流域尺度,其中关键尺度为河岸带100 m至300 m,最有效尺度为河岸带200 m。坡地景观特征影响水质的季节差异随空间尺度不同而变化,在河岸带100 m至300 m尺度为汛期强于非汛期,在河岸带1000 m尺度相反,在子流域尺度无季节差异。建设用地面积比与溶解氧（DO）和高锰酸盐指数（COD_Mn）正相关,耕地面积百分比与氨氮（NH₄⁺-N）参数正相关,两者为水质污染"源景观",且缓坡耕地对水质的解释率高于总地类耕地;林地与水质参数呈负相关,对缓解水质恶化具有积极作用;集聚度（COHESION）、聚合度（AI）指标与NH₄⁺-N参数及斑块密度（PD）、边缘密度（ED）与DO、COD_Mn参数均呈正相关。在集水区尤其是河岸带300 m范围内,严格把控建设用地污水收集与处理,种植河岸带防护林,采取横坡耕种方式,并通过优化景观结构（如种植植物篱）以增强景观拦截力以减少污染物的集中输出,从而改善河流水质。     

不同空间尺度的景观格局对流溪河水质的影响

为探究不同空间尺度的景观格局对流溪河水质的影响,于2020年6月和2021年1月在流溪河干流15个采样点进行了水样的采集,测定了水温、溶解氧、pH、氨氮、硝态氮、硫酸盐和氯化物等水质指标。结合遥感解译所得的土地利用数据,提取了不同空间尺度(子流域和河岸带缓冲区)的景观格局指数,采用Bioenv分析、Mantle检验、方差分解和层次分割理论等方法揭示了景观格局对水质变化的影响。研究结果表明：氨氮是流溪河的主要污染物。土地利用结构与空间格局特征对水质的影响存在空间尺度效应。在100 m河岸带缓冲区,水域是影响水质的主要贡献源;而在其他空间尺度建设用地是影响水质的主要贡献源。在子流域尺度,林地和建设用地的斑块密度(PD指数)是影响水质变化的核心特征;而在河岸带缓冲区尺度,水域和建设用地的连通性(CONTAG指数)和林地的多样性(SHDI指数)是影响水质变化的关键特征。在各个空间尺度,土地利用与空间格局的交互作用对驱动水质变化起主导作用,尤其在1000 m河岸带缓冲区对水质的贡献率最高。因此,加强1000 m缓冲区尺度土地利用的管理和减少建设用地成片建设规划等对保护流域水质具有重要意义。     

不同空间尺度景观特征对南流江水质的影响差异

流域景观特征决定了非点源污染物来源与地表景观削减消纳能力,但尚缺乏全流域不同空间尺度对二者关联性的认识。以广西北部湾南流江为例,分别在子流域、河岸缓冲带以及监测点圆形缓冲区三种尺度上,基于2020年Landsat 8 OLI遥感影像解译的土地利用类型特征,结合水质监测数据,运用数理统计和GIS空间分析方法,探讨了流域景观特征在不同空间尺度上对河流水质的影响。结果表明：(1)在子流域尺度,土地利用类型以林地为主,而在河岸缓冲带与监测点圆形缓冲区均以耕地为主;(2)水质指标高锰酸盐指数、生化需氧量与景观特征相关性最为显著,耕地、建设用地、其他用地和园地与其呈正相关,是南流江水质污染负荷的重要来源区;景观格局指数中,斑块密度、蔓延度指数、多样性指数、均匀度指数是引起河流水质指标变化的主要景观因子;(3)受流域内或不同子流域间景观特征差异,景观组成面积占比和景观格局指数均在河岸缓冲带尺度对水质状况影响最大,分别可解释57.0%和64.7%的水质指标变化;子流域尺度次之,圆形缓冲区尺度最小,且景观格局指数对水质状况的影响大于景观组成面积占比。建议在河岸带50 m范围内严格控制耕地面积,建设河岸缓...     

密云水库上游流域土地利用与地表径流营养物的关系

定量刻画土地利用与水体营养物浓度的关系,有助于指导流域土地利用管理,以控制水体富营养化.以往研究较多关注土地利用的数量结构,对其强度、空间分布等刻画相对不足.本研究以密云水库上游流域为例,基于覆盖全流域52个子流域的水质采样,通过遥感解译和空间计算,提取土地利用强度、所处坡度、与河道及监测断面距离以及位置邻接关系等信息,构建土地利用与总氮、总磷和化学需氧量浓度的多元线性回归方程.结果表明: 土地利用与总氮、总磷和化学需氧量浓度回归方程的决定系数由未纳入任何信息的0.294、0.471和0.223分别增加到0.532、0.685和0.489,显著提高了模型的解释能力.在厘定每一空间位置土地利用对监测断面营养物浓度贡献率的基础上,比较与河道不同迁移路径距离下土地利用对营养物浓度的平均累积贡献率及面积累计百分比,确定了距离河道1 km范围内的河岸带为水体富营养化的关键控制范围.最后提出了优化农田施肥管理、加强牲畜粪便处理、建设林地过滤带和河岸缓冲带等水质污染控制和调控的措施建议.     

不同尺度因子对滦河流域大型底栖无脊椎动物群落的影响

通过2011年滦河流域38个河段大型底栖无脊椎动物采集,探讨了河段尺度和流域尺度环境因子对大型底栖无脊椎动物分布的影响。其中,河段尺度因子包括水体/底质特征、河岸带特征和水质,流域尺度因子包括采样位置、流域土地利用结构和缓冲区土地利用结构。RDA(冗余分析)结果表明,河段尺度影响大型底栖无脊椎动物分布的关键因子为:细粒物质比例、河岸带植被盖度、河岸带人类干扰程度、河岸带农田比例、水面宽度和河道改造程度,总解释量为42%;流域尺度影响大型底栖无脊椎动物分布的关键因子为:纬度、海拔、流域内耕地面积百分比和流域面积,总解释量为32%。研究结果表明,河段尺度因子比流域尺度因子对于指示大型底栖无脊椎动物分布更为重要,在环境因子监测中应给以更多的重视。     

不同河岸缓冲区尺度下土地利用方式对嘎呀河流域水质的影响

土地利用是影响河流水质的重要因素之一，量化不同河岸缓冲区尺度下土地利用方式及空间格局与水质因子之间的关系，对土地利用合理规划及水质改善具有重要意义。本研究以嘎呀河流域为例，基于2021年5月共91个点位的水质调查数据，从河岸缓冲区尺度分析流域土地利用及景观空间分布格局，并采用冗余分析(RDA)和广义加性模型(GAM)探讨土地利用方式及空间分布格局对河流水质的影响。结果表明：总氮是影响嘎呀河水质的首要因素。50、100和500 m河岸缓冲区以耕地为优势土地利用类型，将点位划分为耕地优势组和耕地其他组；1000、1500和2000 m河岸缓冲区以林地为优势土地利用类型，将点位分为林地优势组和林地其他组。100 m河岸缓冲区是对嘎呀河水质指标的最强影响尺度，其次为1000 m河岸缓冲区。林地优势组中，铵氮、电导率、溶解氧、磷酸盐和高锰酸盐指数均受土地利用类型面积占比的显著影响，其中，铵氮浓度随着林地面积占比和耕地面积占比的增加而增大，磷酸盐浓度与Shannon多样性指数(SHDI)显著相关，高锰酸盐指数受SHDI和最大斑块指数(LPI)影响明显。耕地优势组中，总氮浓度受林地面积占比、草地面积...     

南方丘陵区土壤氮素尺度效应的影响因素

利用GPS、GIS和随机过程抽样技术,研究了江西省兴国县潋水河流域土壤氮素在小、中和大3种研究尺度下的分布特征及其影响因素。结果表明,土壤全氮和有效氮尺度效应明显,均值随研究尺度的扩大而增加。其中,土壤全氮平均含量分别是0.60gkg-1、0.73gkg-1和0.83gkg-1,有效氮含量为64.8mgkg-1、66.3mgkg-1和80.2mgkg-1。成土母质、土壤类型、土地利用和土壤侵蚀状况是影响氮素尺度效应的重要因素。3种尺度下母质与土壤氮素含量关系复杂,但均以花岗岩坡残积物发育土壤最低。在不同尺度下,水稻土全氮和有效氮均显著或极显著高于红壤,但大尺度下的石灰岩土与前二种土壤差异均不显著。在小尺度和中尺度下水田全氮显著或极显著高于旱地和林地,在大尺度下它显著高于旱地而与林地差异不显著;水田有效氮显著或极显著高于林地,但与旱地除小尺度下差异达显著水平外,中、大尺度下差异不显著。土壤侵蚀状况对土壤全氮和有效氮含量的影响与尺度大小有关,且随尺度增加差异显著性逐渐增强。     

浙江西苕溪土地利用变化对溪流大型底栖无脊椎动物完整性的影响

土地利用/覆被变化对溪流生态系统的影响是溪流生态学研究的热点.生物完整性是诊断溪流生物学状况和生态健康的重要指标.目的是研究西苕溪流域内土地利用类型对大型底栖无脊椎动物完整性(B-IBI)的影响.利用2003年西苕溪TM数据和DEM模型计算了62个样点上游3种空间尺度下(亚流域、沿岸和局部)的土地利用类型.结果表明,耕地,民居和竹园在流域中的百分比与B-IBI负相关,耕地百分比对B-IBI的影响在亚流域(r=-0.527,p<0.001),河岸(r=-0.665, p<0.001)和局部(r=-0.696, p<0.001)尺度上均显著.针叶林,阔叶林和混交林百分比与B-IBI正相关.阔叶林百分比在亚流域(r=0.333,p<0.001),河岸(r=0.589 ,p<0.001)和局部尺度(r=0.618,p<0.001)与B-IBI显著相关.而针叶林百分比仅在亚流域尺度(r=0.366,p<0.001)与B-IBI显著相关.在研究流域内耕地百分比小于50%的情况下,B-IBI并非随着耕地百分比的增长而线性下降,而是在达到一定阀值后(亚流域尺度,27%;河岸尺度,57%;局部尺度,59%)耕地的影响逐渐趋缓.在耕地百分比小于阀值前,B-IBI在局部尺度上与耕地百分比的增长的关系最强(r=-0.808, p<0.001, n=46).建议在沿岸区增加阔叶林,针叶林与混交林的占有率,或者建立耕地与溪流间的林地缓冲带,有助于保护和恢复西苕溪生态健康.     

崇明岛不同土地利用类型河岸带土壤反硝化酶活性特征

以崇明岛河岸带为研究对象,采用乙炔抑制法,研究了不同土地利用类型河岸带(农田河岸带、林地河岸带、草地河岸带)土壤反硝化酶活性及其影响因素.结果表明：河岸带反硝化酶活性在(0.69±0.11)～(134.93±33.72) μg N·kg^-1·h^-1,不同土地类型河岸带土壤反硝化酶活性存在明显差异,整体趋势为林地河岸带>农田河岸带>草地河岸带.河岸带表层土壤(0～10 cm)反硝化酶活性与其他土层(10～30、30～50和50～70 cm)呈显著差异(P<0.05).反硝化酶活性与土壤有机碳、土壤全氮和土壤硝态氮呈极显著正相关关系(P<0.01).土地利用类型的变化主要通过改变河岸带土壤自然结构和理化性质、降低土壤有机质的积累、影响土壤氮素的转化,从而抑制河岸带土壤反硝化作用的发生.     

Riparian control on NO3 −, DOC, and dissolved Fe concentrations in mountainous streams, northern Japan

We evaluated (1) the longitudinal pattern of stream chemistry and (2) the effects of the riparian zone on this longitudinal pattern for nitrate (NO₃ ⁻), dissolved organic carbon (DOC), and total dissolved iron (Fe). We selected two small watersheds; the “southern watershed” had an extending riparian wetland and the “northern watershed” had a narrow riparian area. Stream NO₃ ⁻ concentrations decreased from the spring to outlet of both watersheds. In the southern watershed, stream DOC concentration decreased from the spring to midstream and then increased to the outlet. Stream Fe concentration in the southern watershed longitudinally increased. On the other hand, the northern watershed exhibited no longitudinal pattern for DOC and Fe concentrations. In both watersheds, while NO₃ ⁻ concentrations in the soil and ground water were lower than those in the stream waters, DOC and Fe concentrations exhibited the opposite patterns. The longitudinal decreases of NO₃ ⁻ concentrations in both streams and increase of stream Fe in the southern watershed mainly resulted from the inflow of the soil and ground water to the stream. The decrease in stream DOC from the spring to midstream in the southern watershed was due to the deep groundwater having low DOC, while the subsequent increase to the surrounding soil and ground water. Moreover, considerations of stream solute flow with soil and ground water chemistry suggested other mechanisms adding NO₃ ⁻ and removing/diluting DOC and Fe, especially for the northern watershed; coexistence of oxidizing and reducing conditions in the riparian zone might control the longitudinal concentration change in the stream water chemistry.     

Molecular biomarkers in the subsurface of the Salar Grande (Atacama,Chile) evaporitic deposits

Denitrification in riparian wetlands plays a major role in eliminating nitrate coming from agricultural watershed uplands before they reach river water. A new approach was developed for representing this process in the biogeochemical Riverstrahler model, using a single adjustable parameter representing the potential denitrification rate of wetland soils. Applied to the case of three watersheds with contrasting size, land-use and hydro-climatic regime, namely the Seine and the Loir rivers (France) and the Red River (Vietnam), this new model is able to capture the general level of nitrate concentrations as well as their seasonal variations everywhere over the drainage network. The nitrogen budgets calculated from the results show that riparian denitrification eliminates between 10 and 50% of the diffuse sources of nitrogen into the hydrosystem coming from soil nitrate leaching.     

Relationship between biodiversity and landscape structure in the Gyungan stream basin,central Korea

The relationship between landscape structure and biodiversity was investigated in the Gyungan stream basin, central Korea, in order to prepare a biodiversity conservation plan. The study area was divided into upstream, midstream, downstream and Gonjiam stream sub‐watersheds based on the land use pattern of each sub‐watershed. The quality of the terrestrial landscape was assessed by connectivity and percentages of deciduous broad‐leaved forest and urbanized area. The quality of the terrestrial landscape was the highest in the downstream sub‐watershed followed by Gonjiam stream, midstream and upstream sub‐watersheds. The quality of the riparian landscape assessed by percentages of the number and the area that the wetland vegetation elements occupy in the whole area showed a similar trend to that of terrestrial landscape. The diversity of all taxa including fish, reptiles and amphibians, birds, mammals and wetland vegetation except benthic macroinvertebrates was the highest downstream. The diversity of benthic macroinvertebrates was the highest in the Gonjiam stream sub‐watershed. Thus, biodiversity was shown to be the highest in the downstream sub‐watershed, followed, in order, by Gonjiam stream, midstream and upstream sub‐watersheds in proportion to landscape quality. On the other hand, the quality of the aquatic environment based on the ecological score of benthic macroinvertebrate (ESB) index was the highest downstream, followed, in order, by upstream, Gonjiam stream and midstream areas. This trend is different from that of biodiversity. In order to improve landscape quality degraded by excessive land use and to increase biodiversity, we recommended a restoration plan that addresses both ecosystem and landscape.     

Dissolved Organic Carbon in Headwater Streams and Riparian Soil Organic Carbon along an Altitudinal Gradient in the Wuyi Mountains,China

Stream water dissolved organic carbon (DOC) correlates positively with soil organic carbon (SOC) in many biomes. Does this relationship hold in a small geographic region when variations of temperature, precipitation and vegetation are driven by a significant altitudinal gradient? We examined the spatial connectivity between concentrations of DOC in headwater stream and contents of riparian SOC and water-soluble soil organic carbon (WSOC), riparian soil C:N ratio, and temperature in four vegetation types along an altitudinal gradient in the Wuyi Mountains, China. Our analyses showed that annual mean concentrations of headwater stream DOC were lower in alpine meadow (AM) than in subtropical evergreen broadleaf forest (EBF), coniferous forest (CF), and subalpine dwarf forest (SDF). Headwater stream DOC concentrations were negatively correlated with riparian SOC as well as WSOC contents, and were unrelated to riparian soil C:N ratio. Our findings suggest that DOC concentrations in headwater streams are affected by different factors at regional and local scales. The dilution effect of higher precipitation and adsorption of soil DOC to higher soil clay plus silt content at higher elevation may play an important role in causing lower DOC concentrations in AM stream of the Wuyi Mountains. Our results suggest that upscaling and downscaling of the drivers of DOC export from forested watersheds when exploring the response of carbon flux to climatic change or other drivers must done with caution.     

三江平原流域湿地景观破碎化过程研究

以流域为研究单元,利用历史图件和遥感数据资料及GIS技术,系统分析了该区典型流域50年来湿地景观的破碎化过程.结果表明,该区湿地景观破碎化在斑块个体和空间结构两方面变化极大.景观斑块个体变化主要表现为最大斑块、平均斑块面积不断缩小,斑块密度不断增大,斑块形状破碎化指数不断增大,景观内部生境面积破碎化指数不断上升;空间结构变化主要表现为湿地景观由初始基质景观逐渐变为河岸带景观;同时,随着农田面积逐渐扩大,隔离湿地斑体数量不断上升,隔离度不断增大;景观空间分布模式由“大陆-岛屿模式”向“卫星型模式”转变,最后变化为“完全隔离型模式”.导致该区湿地景观破碎化的主导因素是大规模的农业开发,反映了人类活动对湿地景观的巨大影响.     

流域尺度上河流水质与土地利用的关系

以苏子河流域内54个水质采样点为基点,生成6种尺度的河岸带缓冲区,并借助FRAGSTATS软件计算景观水平和类型水平上的8种景观指数.分别从景观空间格局与景观类型组成两方面,对景观指数与水质进行相关分析.结果表明:区域景观格局在不同缓冲区内对流域水质具有不同的效应.当缓冲区距离≤300 m时,旱地、建筑用地、水田为主要的景观类型组成,其面积比例、斑块数量、斑块密度、最大斑块指数、最大形状指数、景观斑块聚集度指数均较高,农田的连通性较高,对水质的影响较大.在距离河流较远的区域(缓冲区距离＞300 m),林地面积比例较高,林地聚集连通程度较好,对水质改善具有一定作用,但不明显.该流域耕地、建设用地等对水质有着关键的影响作用.     

Effects of native perennial vegetation buffer strips on dissolved organic carbon in surface runoff from an agricultural landscape

Dissolved organic carbon (DOC) constitutes a small yet important part of a watershed’s carbon budget because it is mobile and biologically active. Agricultural conservation practices such as native perennial vegetation (NPV) strips will influence carbon cycling of an upland agroecosystem, and could affect how much DOC enters streams in runoff, potentially affecting aquatic ecosystems. In a study conducted in Iowa (USA), four treatments with strips of NPV varying in slope position and proportion of area were randomly assigned among 12 small agricultural watersheds in a balanced incomplete block design. Runoff samples from 2008 to 2010 were analyzed for DOC and correlated with flow data to determine flow weighted DOC concentrations and loads. Data were analyzed for the entire 3 years, annually, seasonally, monthly, by flow event size and for one extreme storm event. Overall we found few differences in DOC concentration with the exception that concentrations were greater in the 10 % NPV at the footslope watersheds than the 20 % NPV in contours watersheds over the 3 years, and the 100 % agricultural treatment had higher DOC concentrations than all NPV treatments during the one extreme event. Because the NPV treatments reduced runoff, DOC export tended to be highest in the 100 % agricultural watersheds over the 3 years and during high flows. We also compared two watersheds that were restored to 100 % NPV and found decreases in DOC concentrations and loads indicating that complete conversion to prairie leads to less watershed DOC export. Regression results also support the contention that increases in the percentage of NPV in the watershed decreases watershed export of DOC. Further analysis indicated that DOC concentrations were diluted as flow event size increased, independent of any treatment effects. It appears groundwater sources become an important component to flow as flow event size increases in these watersheds.     

Stormflow Dynamics of Dissolved Organic Carbon and Total Dissolved Nitrogen in a Small Urban Watershed

We examined patterns of dissolved organic carbon (DOC) and total dissolved nitrogen (TDN) loading to a small urban stream during baseflow and stormflow. We hypothesized that lower DOC and TDN contributions from impervious surfaces would dilute natural hydrologic flowpath (i.e., riparian) contributions during storm events in an urban watershed, resulting in lower concentrations of DOC and TDN during storms. We tested these hypotheses in a small urban watershed in Portland, Oregon, over a 3-month period during the spring of 2003. We compared baseflow and stormflow chemistry using Mann–Whitney tests (significant at p<0.05). We also applied a mass balance to the stream to compare the relative significance of impervious surface contributions versus riparian contributions of DOC and TDN. Results showed a significant increase in stream DOC concentrations during stormflows (median baseflow DOC = 2.00 mg l⁻¹ vs. median stormflow DOC = 3.46 mg l⁻¹). TDN streamwater concentrations, however, significantly decreased with stormflow (median baseflow TDN = 0.75 mg l⁻¹ vs. median stormflow TDN = 0.56 mg l⁻¹). During storms, remnant riparian areas contributed 70–74% of DOC export and 38–35% of TDN export to the stream. The observed pattern of increased DOC concentrations during stormflows in this urban watershed was similar to patterns found in previous studies of forested watersheds. Results for TDN indicated that there were relatively high baseflow nitrogen concentrations in the lower watershed that may have partially masked the remnant riparian signal during stormflows. Remnant riparian areas were a major source of DOC and TDN to the stream during storms. These results suggest the importance of preserving near-stream riparian areas in cities to maintain ambient carbon and nitrogen source contributions to urban streams.     

The significance of storms for the concentration and export of dissolved organic carbon from two Precambrian Shield catchments

Dissolved organic carbon (DOC) concentrations and DOC export arestudied during storms to examine the relationship between DOCconcentration and stream discharge and to assess the importance of stormson DOC export. Storms were monitored in seven subcatchments within twosmall watersheds (Harp 4--21 and Harp 3A) on the Precambrian Shield inCentral Ontario, Canada. Stream DOC concentrations increase during stormsby as much as 100% and 410% in Harp3A and Harp 4--21 respectively. The seasonal regression between DOC andstream discharge is significant in subcatchments without wetlands(r² > 0.7) but is not significant in thetwo subcatchments with small wetland areas (r² <0.06). On average, regressions based on weekly data yield accurate estimatesof DOC export but the variation in regressions among individual storms andthe small number of high DOC samples result in uncertainties of more than30% in DOC export. The period-weighted calculation ofDOC export from weekly data underestimates export by 14%and 22% in Harp 3A and Harp 4--21 respectively. Stormswere responsible for 57% to 68% of theDOC export in the autumn and 29% to 40%of the DOC export in the spring. A single large storm accounted for31% of the autumn DOC export in Harp 3A. The importanceof individual storms for DOC export and the variation in the relationshipbetween DOC and stream discharge among storms make it difficult to predictthe effects of climate change on DOC export and DOC concentrations.     

Sources and flowpaths of dissolved organic carbon during storms in two forested watersheds of the Precambrian Shield

Dissolved organic carbon (DOC) concentrations and export were studied in two small catchments in central Ontario to examine DOC sources and to assess the hypothesis that organic matter adjacent to the stream is a significant contributor of DOC during storms. Different DOC dynamics and exports were observed according to the depth of the riparian water table. In Harp 4-21, riparian flowpaths were predominantly through A and upper B soil horizons and riparian soils contributed between 73 and 84% of the stream DOC export during an autumn storm. In Harp 3A, riparian flowpaths were predominantly through lower B horizons. Consequently, riparian soils were less important and hillslopes contributed more than 50% of the stream DOC export in subcatchments without wetlands during storms. Wetlands and adjacent soils contributed significantly to DOC export in Harp 3A; 8% of the total catchment area exported 32 to 46% of the storm runoff DOC. DOC export dynamics in wetlands and riparian soils were distinctly different. In wetlands, transport was affected by leaching and flushing of DOC at the wetland surface leading to lower DOC concentrations with successive storms. In riparian soils, groundwater flowpaths were more important and stronger positive relationships between discharge and DOC concentration were observed. Precipitation, throughfall and stemflow were minor sources of stream DOC during storms and contributed less than 20% of the total export.