潜流人工湿地中植物对氮磷净化影响效应的研究

采用潜流人工湿地系统,配制以NH⁺₄-N、NO^-₃-N和PO^3-₄-P为主要成分的模拟污水,通过间歇运行方式,考察了芦苇和小叶章的生长情况、生理生态学特性及其对污水中N、P净化效能的影响,并研究了植物对湿地系统pH变化、NO^-₃-N和NH⁺₄-N净化效率的影响。结果表明,当水力停留时间为7d时,小叶章和芦苇湿地对TN的去除率分别为65.1%和99.6%,去除负荷分别为1.66g · m^-3 · d^-1和2.53g · m^-3 · d^-1。小叶章和芦苇对去除TN的贡献率分别为14.7%、61.7%,对去除TP的贡献率分别为11.7%和12.9%;芦苇植株内N、P浓度分别为29.2mg/g和3.41mg/g。芦苇湿地的净化效能高于小叶章湿地。湿地系统中pH值先升高后降低的拐点可作为氨氧化反应结束的指示参数。     

施氮量对麻疯树幼苗生长及叶片光合特性的影响

采用盆栽土培的方法,研究了不同施氮量(对照N₀ 0 kg N/hm²、低氮N_L 96 kg N/hm²、中氮N_M 288 kg N/hm²、高氮N_H 480 kg N/hm²)对麻疯树幼苗生长、叶片气体交换及叶绿素荧光参数的影响。结果表明,麻疯树幼苗叶片氮含量、可溶性蛋白含量、株高、地径、叶片数量、叶面积、根长、各组分生物量、叶片净光合速率(P_n)、气孔导度(G_s)、蒸腾速率(T_r)和水分利用效率(WUE)均随施氮量的增加先升高后降低,N_M处理下麻疯树幼苗长势最好,各气体交换参数值最高;施氮对麻疯树地上部分的促进作用远大于地下部分,施氮后根冠比显著降低;此外,麻疯树叶绿素含量、PSⅡ最大光化学量子产量(Fv/Fm)、PSⅡ有效量子产量(F'v/F'm)、PSⅡ实际光化学效率(Φ_PSⅡ)、电子传递速率(ETR)和光化学淬灭系数(qP)均随施氮量的增加而升高,非光化学淬灭系数(NPQ)随施氮量增加而降低。适量施氮可通过增强叶绿体光化学活性、气孔导度和羧化能力而提高麻疯树幼苗的光合能力,促进生长;过高施氮对麻疯树幼苗光合与生长的促进效应降低。试验条件下,当年生麻疯树幼苗的最适施氮量为288 kg N/hm²。     

预处理方式对香蒲和芦苇种子萌发的影响

有性繁殖是植物种群形成与维持的主要方式。为探索退化湿地的快速恢复方法,为松花江下游退化湿地恢复提供科学依据,本研究开展了香蒲和芦苇种子快速发芽的有性繁殖实验。研究采用滤纸为发芽基质,通过变温培养试验,以未浸种处理为参照,分析了蒸馏水、双氧水(H₂O₂)、硝酸钾(KNO₃)和高锰酸钾(KMnO₄)溶液浸种的预处理方式对香蒲、芦苇种子发芽率和发芽速率的影响。结果表明:不同预处理方式对香蒲、芦苇种子的发芽率和发芽速率均具有显著影响。KMnO₄溶液浸种再清洗处理条件下,香蒲种子发芽率和发芽速率均显著高于其他处理,平均发芽率可达未浸种处理条件下的3.1倍,发芽速率为16.17±0.80。芦苇种子的发芽率和发芽速率在经KNO₃溶液浸泡再清洗处理后效果最佳,种子发芽率达96%-99%,发芽速率达28.43±0.71。因此,分别对香蒲、芦苇种子采用KMnO₄和KNO₃溶液浸泡再清洗的预处理方式可以缩短出苗时间,提高发芽率,从而加速湿地植被恢复进程。     

鄱阳湖苔草湿地甲烷释放特征

2009年5月-2010年4月在鄱阳湖南矶湿地国家级自然保护区选择以灰化苔草为建群种的洲滩,设置土壤-植物系统(TC)、剪除植物地上部分 (TJ)2个试验处理,利用密闭箱-气相色谱法测定了鄱阳湖典型苔草湿地的甲烷(CH₄)释放通量。结果表明:1)TC、TJ 2个试验处理CH₄释放速率变化范围分别为-0.094-17.75 mg · m^-2 · h^-1、-0.122-19.16 mg · m^-2 · h^-1,均表现出明显的季节变化规律;2)地表未淹水期间,剪草处理CH₄释放显著高于非剪草处理(t=2.69, P<0.05);地表淹水达到15 cm后,剪草处理CH₄释放明显低于非剪草处理。3)土壤5 cm温度、土壤水分与2处理非淹水期间CH₄释放速率均呈显著正相关,是非淹水期间CH₄通量变化的主要控制因子,2因子能够共同解释非淹水期苔草湿地65%-74%的CH₄通量变异;4)试验期间,苔草湿地CH₄释放量约为12.77 gC/m²,相当于同期土壤有机质分解碳排放量的4%,甲烷释放的碳消耗不足苔草湿地年NPP的1%。     

濒危种四合木与其近缘种霸王水分关系参数和光合特性的比较

运用压力室-容积技术(P-V技术)对西鄂尔多斯地区特有的濒危植物四合木(Tetraena mongolica Maxim.)和生长于同一生境的近缘种霸王(Zygophyllum xanthoxylon (Bunge) Maxim.)的7个水分关系参数饱和含水量时最大渗透势(Ψ_s^sat) 、初始质壁分离时的渗透势(Ψ_s^tlp) 、初始质壁分离时渗透水相对含量(ROWC^tlp) 、初始质壁分离时的相对含水量(RWC^tlp) 、质外体水的相对含量(AWC) 、束缚水与自由水的比值(V_a / V₀),以及细胞最大弹性模量(ε^max)进行了测定,同时利用Li-6400光合作用测定系统测定了二者叶片气体交换参数的日变化,从生理生态学角度探讨了二者生存力、适应力的差异。结果表明:1)四合木的ε^max、ROWC^tlp值和RWC^tlp值均显著低于霸王,而Ψ_s^sat值Ψ_s^tlp值、AWC和V_a / V₀高于霸王。二者保持膨压的能力和方式不同,四合木表现为较小的细胞体积和较强的持水能力,主要以高的组织弹性来保持膨压,而霸王主要以增加细胞质浓度的渗透调节来维持膨压,弹性调节较弱。且四合木保持最大膨压的能力和维持最低膨压的极限渗透势低于霸王,耐旱性弱于霸王。2)自然条件下,四合木和霸王叶片的光合速率(Pn)、蒸腾速率(Tr)日进程均呈"双峰"曲线,主峰出现在11:00时,次峰出现在15:00时左右,光合作用的午间降低是由气孔导度(Gs)降低造成的。二者相比,四合木光合速率和水分利用效率(WUE)低于霸王,光合能力和对干旱环境适应能力弱于霸王。研究表明四合木在生理生态学方面的生存力、适应力弱于霸王。     

成熟马占相思林的蒸腾耗水及年际变化

利用Granier测定系统对华南丘陵植被恢复先锋群落马占相思林的树干液流进行了连续4a(2004-2007年)的监测研究,以了解已过生长高峰的马占相思林(20-22林龄)的水分利用特征。结果显示,液流密度(J_s)日变化为单峰型曲线,具有明显的季节差异,湿季J_s日变化幅度和峰值J_smax均大于干季。J_s与光合有效辐射(PAR)和水汽压亏缺(VPD)的偏相关分析显示,J_s与PAR或VPD正相关,干季的相关性较湿季显著;线性回归分析显示PAR和VPD对J_s日变化共同影响的程度达62.7%-82.7%。马占相思整树和林分的蒸腾强度和耗水量均表现出明显的干湿季差异,湿季明显高于干季。偏相关分析表明降雨量对蒸腾活动没有显著的直接影响,而PAR与蒸腾量显著相关,是影响林分蒸腾量的最重要环境因子。2004-2007年各年马占相思成熟林的蒸腾耗水量为238.64、136.39、217.45mm和273.85mm,分别占当年降雨量的24.7%、11.7%、9.8%和22.8%,年平均蒸腾耗水量为243.31±28.49 mm(n=3),降水对林分蒸腾的影响不仅仅取决于降雨量的大小,较多的降雨频次往往会削弱蒸腾的强度。研究的马占相思林处于生长后期,群落叶面积指数和蒸腾已有明显的下降,反映出该阶段林分已不能充分利用当地的辐射和水分资源,必要的林分改造可提高造林后期的生产效益。     

华北平原玉米田生态系统光合作用特征及影响因素

采用涡度相关法对华北平原夏玉米田进行了连续4a(2003-2006年)的碳通量观测,结果表明:夏玉米田生态系统初始量子效率(α)、最大光合速率(P_max)、暗呼吸速率(R_d)和总初级生产力(GPP)随作物生长发育而变化。在夏玉米生育前期和后期,α、P_max、R_d和GPP都比较小,其最大值出现在抽穗期/灌浆期。2003-2006年,夏玉米生长季平均α、P_max、R_d的范围分别为0.054-0.124 μmol/μmol、1.72-2.93 mg CO₂ · m^-2 · s^-1、0.23-0.38 mg CO₂ · m^-2 · s^-1。α、P_max和R_d均随叶面积指数(LAI)增加呈指数增长。2003-2006年夏玉米生长季GPP总量分别为806.2、741.5、703.0、817.4 g C/m²,年际差异较大。玉米田生态系统GPP随温度升高呈指数增长。在玉米营养生长阶段,GPP随LAI增加而增大,两者之间的关系可用直角双曲线方程来表示;生殖生长阶段,GPP随LAI降低而下降.相同LAI下,生殖生长阶段的GPP明显低于营养生长阶段。     

苹果三维树冠的净光合速率分布模拟

构建三维树冠光合模型可模拟出叶片净光合速率(P_n)、气孔导度(G_s)和光能利用效率(LUE)在树冠内的三维分布。以17年生纺锤形"富士"苹果树(Malus domestica Borkh. cv. ‘Fuji’)为试材,通过实测确定三维树冠内叶片和辐射分布,根据不同部位叶片最大光合速率经验公式模拟叶片P_n 在三维树冠空间内分布,并据2007-2009年测定数据拟合相关模型参数。模拟表明,苹果树冠叶片P_n 和辐射的三维分布相似,在树冠上部P_n 三维分布比较平缓,然后随辐射的减少而迅速降低。高辐射条件下(PAR=1500 μmol·m^-2·s^-1),从树冠上部3 m处降到到1 m,平均相对辐射从71.18%降到8.05%,减少了89%,叶片平均P_n从15.05 μmol·m^-2·s^-1降到1.92 μmol·m^-2·s^-1,减少了87%。单位体积小室内的总净光合速率大小主要取决于叶面积密度,部分取决于P_n。G_s三维分布与P_n相似,而LUE分布与辐射相反,中下部高,上部低。根据光合机理模型、树冠内辐射和叶面积三维分布可模拟出苹果三维树冠内叶片的P_n、G_s和LUE分布,该模型参数少,可方便用于其它果树三维光合模型构建和果树整形修剪研究。     

水葱和香蒲叶经济性状对模拟增温和CO2浓度倍增的响应

气候变化是国际社会共同关注的环境问题,植物对气候变化的响应反映了植物应对气候变化的生长和生存策略。叶经济性状与植物对资源的获取、利用和储存直接相关,并且受到温度条件和CO₂浓度的显著影响。该文采用人工环境控制系统封顶式生长室研究广布湿地植物水葱(Scirpus validus)和香蒲(Typha orientalis)的叶经济性状对模拟增温(现行环境温度+2 ℃)和CO₂浓度倍增(增至850 μmol·mol^-1)的响应。结果表明:(1)增温处理下,水葱净光合速率、氮含量和磷含量显著降低,但其胞间CO₂浓度和比叶重显著增加; CO₂浓度倍增处理下,水葱胞间CO₂浓度和净光合速率均显著降低,但比叶重显著增加。(2)增温处理下香蒲的比叶重显著增加,而氮含量和磷含量显著降低; 香蒲的光合参数、氮含量和磷含量在CO₂浓度倍增处理下均显著降低,而比叶重显著增加。(3)水葱的比叶重、氮含量、磷含量、净光合速率、气孔导度、胞间CO₂浓度与主成分分析的两个环境变量相关; 而香蒲的经济性状均与两个环境变量相关,表明这些经济性状在香蒲响应增温和CO₂浓度变化过程中发挥重要作用。(4)除碳含量外,水葱和香蒲的其他经济性状参数包括净光合速率、气孔导度、蒸腾速率、胞间CO₂浓度、氮含量、磷含量和比叶重均在响应增温和CO₂浓度倍增过程中发挥重要作用。总体而言,该研究结果反映了水葱和香蒲在功能性状上对增温和CO₂浓度倍增的响应策略。两种植物的光合能力和养分含量在两种处理下虽然均受到显著的抑制作用,但是其抗逆能力升高,表明增温和CO₂浓度升高不利于水葱和香蒲的生长。     

秸秆不同还田量对宁南旱区土壤水分、玉米生长及光合特性的影响

在宁南半干旱区通过大田定位试验研究了不同秸秆还田量对农田土壤水分、春玉米生长性状、关键生育期光合特性及产量的影响。试验设计为3个秸秆还田量水平,小麦秸秆按3000 kg/hm²(L)、6000 kg/hm²(M)、,9000 kg/hm²(H)粉碎还田;玉米秸秆按4500 kg/hm²(L) 、9000 kg/hm²(M)、13500 kg/hm²(H)粉碎还田,对照为秸秆不还田。每个处理设3次重复,随机区组排列,秸秆被粉碎机打碎成5cm左右的小段,人工均匀翻埋至25cm左右深度的土层。结果表明,不同秸秆还田量(高、中、低)下, 播前各处理0-200cm土层土壤贮水量均较CK(对照)有显著提高, 秸秆还田量由高到低,0-200cm土层土壤贮水量增加量是30.17-32.83 mm,不同还田量之间没有显著差异。玉米株高、茎粗和单株叶面积显著增加,和对照比较差异达显著水平(P<0.05)。还田处理玉米叶片的光合速率和蒸腾速率在12:00-15:00持续出现高值,高、中、低3个秸秆还田量处理的叶片光合速率分别显著高出对照6.52、3.74、3.20μmol · m^-2 · s^-1 (P<0.05),蒸腾速率分别高于对照2.08、1.63、0.72μmol · m^-2 · s^-1 。随秸秆还田量由高到低,高、中、低3个不同秸秆还田量处理的玉米籽粒产量较对照分别提高了58.3%、36.7%和5.4%,玉米水分利用效率(WUE)较CK分别提高38.5％、31％和0.9％。秸秆还田可提高土壤的水分利用率和蓄水能力,促进作物的光合作用,进而使作物增产。不同土壤含水量条件下,光合速率、蒸腾速率的日变化规律不同,土壤水分亏缺对干旱地区作物光合作用来说将是最大的限制因子。     

Nutrient removal in constructed microcosm wetlands for treating polluted river water in northern China

River water pollution is increasingly widespread in northern China and can lead to problems with the drinking water for the residents if not properly treated. Constructed wetlands are a promising solution and have become increasingly popular in China. In this study the nutrient removal and plant uptake in constructed microcosm wetlands vegetated with Typha orientalis, Phragmites australis, Scirpus validus and Iris pseudacorus for treating simulated polluted river water in northern China were investigated. The performance of the treatment systems from April to November was assessed. The maximum TN, NH₄-N and TP removal efficiencies were 68%, 93% and 67%, respectively. And the maximum nutrient uptake by plants constituted 51.89% of the N removal and 34.17% of the P removal throughout the trial. S. validus and I. pseudacorus have a higher nutrient uptake capacity and are preferred species from a treatment perspective in constructed wetland in northern China.     

Chemical oxygen demand,nitrogen and phosphorus removal by subsurface wetlands with Phragmites vegetation in different models

To improve the removal efficiency of subsurface wetlands vegetated mainly by Phragmites, pilot‐scale gravel‐based wetlands were used to treat sewage characterized by chemical oxygen demand (COD), total nitrogen (TN) and total phosphorus (TP) pollution. For Phragmites vegetation, COD, TP and TN removal loads of wetland vegetation with Phragmites australis–Typha angustata–Scirpus validus as main species reached 0.517 g m^?2 d^?1, 0.277 g P m^?2 d^?1 and 0.023 g N m^?2 d^?1. The COD removal loads in pilot‐scale and medium‐scale (260 m² in area) wetlands with Phragmites‐monoculture vegetation were 0.62–0.64 g m^?2 d^?1, while that of P. australis–T. angustata–S. validus wetland reached 0.974 g m^?2 d^?1. Thus, the preferable poly‐culture model for Phragmites wetland vegetation was P. australis, T. angustata, S. validus and Zizania latifolia with stem density ratio of 8:1:5:1. After harvest, nitrogen and phosphorus standing stocks of wetland vegetations ranged only 2.2–9.93 g N m^?2 and 5.39–13.5 g P m^?2, respectively, as both the above ground biomass and the nitrogen and phosphorus contents of the wetland vegetation harvested in late autumn were low.     

Effect of plant and artificial aeration on solids accumulation and biological activities in constructed wetlands

In constructed wetlands, solids accumulation may have two consequences with opposing effects on treatment efficiency: it decreases the longevity by reducing void space and it enhances biological activity by favoring biofilm development. The goal of our study was to estimate the effect of plants (presence and species) and artificial aeration on solids accumulation (volatile and inorganic). The horizontal and vertical distribution of solids was sampled using solids traps in 12 constructed wetland mesocosms (5 years old). Microbial density and activity were estimated in the biological fraction of the sampled solids. The effect of plant presence reduced accumulated solids by 26% and sulphide content by 50% sulphide content. There was more solids accumulation in Typha angustifolia units than in Phragmites australis. Also, T. angustifolia generated more biological activities at the surface and close to the inlet while conditions were more homogeneous throughout P. australis units. Aeration (1) stimulated biofilm development at the inlet of planted beds, (2) seemed to reduce mineral matter accumulation and (3) generated the same pattern of activities in planted beds enabling to reach a total nitrogen removal rate of up to 0.65 g N m^?2 d^?1.     

Comparison of the diversity of root-associated bacteria in Phragmites australis and Typha angustifolia L. in artificial wetlands

Common reed (Phragmites australis) and narrow-leaved cattail (Typha angustifolia L.) are two plant species used widely in artificial wetlands constructed to treat wastewater. In this study, the community structure and diversity of root-associated bacteria of common reed and narrow-leaved cattail growing in the Beijing Cuihu Wetland, China, were investigated using 16S rDNA library and PCR–denaturing gradient gel electrophoresis methods. Root-associated bacterial diversity was higher in common reed than in narrow-leaved cattail. In both plant species, the dominant root-associated bacterial species were Alpha, Beta and Gamma Proteobacteria, including the genera Aeromonas, Hydrogenophaga, Ideonella, Uliginosibacterium and Vogesella. Acidobacteria, Actinobacteria, Nitrospirae and Spirochaetes were only found in the roots of common reed. Comparing the root-associated bacterial communities of reed and cattail in our system, many more species of bacteria related involved in the total nitrogen cycle were observed in reed versus cattail, while species involved in total phosphorus and organic matter removal were mainly found in cattail. Although we cannot determine their nutrient removal capacity separately, differences in the root-associated bacterial communities may be an important factor contributing to the differing water purification effects mediated by T. angustifolia and P. australis wetlands. Thus, further work describing the ecosystem functions of these bacterial species is needed, in order to fully understand how effective common reed- and narrow-leaved cattail-dominated wetlands are for phytoremediation.     

Elevated Atmospheric CO<Subscript>2</Subscript> Increases Root Exudation of Carbon in Wetlands: Results from the First Free-Air CO<Subscript>2</Subscript> Enrichment Facility (FACE) in a Marshland

Experiments employing free-air CO₂ enrichment (FACE) facilities have indicated that elevated atmospheric carbon dioxide (eCO₂) stimulates growth in diverse terrestrial ecosystems. Studies of the effects of eCO₂ on wetland plants have indicated a similar response, but these studies were mostly performed in growth chambers. We conducted a 2-year FACE experiment [CO₂ ≈ 582 µmol mol^?1] in a marsh in Spain to test whether the common reed (Phragmites australis) responds to carbon enrichment, as previously reported in other macrophytes. More specifically, we tested the effect of eCO₂ on P. australis growth, photosynthesis, transpiration, and biomass, its effect on modifying plant and soil ratios of carbon, nitrogen, and phosphorus, and whether the strong environmental variability of this wetland modulates these responses. Our findings show that effects of eCO₂ in this wetland environment are more complex than previously believed, probably due to hydrological effects. The effects of eCO₂ on reed plants were cumulative and manifested at the end of the growing season as increased 38–44% instantaneous transpiration efficiency (ratio of net photosynthesis to transpiration), which was dependent on plant age. However, this increase did not result in a significant increase in biomass, because of excessive root exudation of carbon. These observations contrast with previous observations of wetland plants to increased atmospheric CO₂ in growth chambers and shed new light on the role of wetland plants as a carbon sink in the face of global climate change. The combined effects of water stress, eCO₂, and soil carbon processes must be considered when assessing the function of wetlands as a carbon sink under global change scenarios.     

Use of horizontal subsurface flow constructed wetlands to treat reverse osmosis concentrate of rolling wastewater

According to the characteristics of the reverse osmosis concentrate (ROC) generated from iron and steel company, we used three sets of parallel horizontal subsurface flow (HSF) constructed wetlands (CWs) with different plants and substrate layouts to treat the high-salinity wastewater. The plant growth and removal efficiencies under saline condition were evaluated. The evaluation was based entirely on routinely collected water quality data and the physical and chemical characteristics of the plants (Phragmites australis, Typha latifolia, Iris wilsonii, and Scirpus planiculmis). The principal parameters of concern in the effluent were chemical oxygen demand (COD), total nitrogen (TN), and total phosphorus (TP). The results showed that the CWs were able to remove COD, TN, and TP from ROC. S. planiculmis was not suitable for the treatment of high-saline wastewater. The sequence of metals accumulated in CW plants was K>Ca>Na>Mg>Zn>Cu. More than 70% of metals were accumulated in the aboveground of P. australis. The CW filled with gravel and manganese ore and planted with P. australis and T. latifolia had the best performance of pollutant removal, with average removal of 49.96%, 39.45%, and 72.01% for COD, TN, and TP, respectively. The effluent water quality met the regulation in China. These results suggested that HSF CW planted with P. australis and T. latifolia can be applied for ROC pollutants removal.     

A three-stage experimental constructed wetland for treatment of domestic sewage: First 2 years of operation

Hybrid constructed wetland systems have recently been used to treat wastewaters where high demand for removal of ammonia is required. However, these systems have not been used too often for small on-site treatment systems. This is because in many countries ammonia is not limited in the discharge from small systems. Hybrid systems have a great potential to reduce both ammonia and nitrate concentrations at the same time. In our study we employed a three-stage constructed wetland system consisting of saturated vertical-flow (VF) bed (2.5 m², planted with Phragmites australis), free-drained VF bed (1.5 m², planted with P. australis) and horizontal-flow (HF) bed (6 m², planted with Phalaris arundinacea) in series. All wetlands were originally filled with crushed rock (4-8 mm). However, nitrification was achieved only after the crushed rock was replaced with sand (0-4 mm) in the free-drain wetland. Also, original size of crushed rock proved to be too vulnerable to clogging and therefore, in the first wetlands the upper 40 cm was replaced by coarser fraction of crushed rock (16-32 mm) before the second year of operation started. The system was fed with mechanically pretreated municipal wastewater and the total daily flow was divided into two batches 12 h apart. The evaluation of the results from the period 2007 to 2008 indicated that such a system has a great potential for oxidation of ammonia and reduction of nitrate. The ammonia was substantially reduced in the free-drained VF bed and nitrate was effectively reduced in the final HF bed. The inflow mean NH₄-N concentration of 29.9 mg/l was reduced to 6.5 mg/l with the average removal efficiency of 78.3%. At the same time the average nitrate-N concentration rose from 0.5 to only 2.7 mg/l at the outflow. Removal of BOD₅ and COD amounted to 94.5% and 84.4%, respectively, with respective average outflow concentrations of 10 and 50 mg/l. Phosphorus was removed efficiently despite the fact that the system was not aimed at P removal and therefore no special media were used. Phosphorus removal amounted in 2008 to 65.4%, but the average outflow concentration of 1.8 mg/l is still high. The results of the present study indicate very efficient performance of the hybrid constructed wetlands, but optimal loading parameters still need to be adjusted. The capital cost of the experimental system is comparable to the conventional on-site treatment plant but the operations and maintenance costs are about one third of the conventional plant.     

基于湿地植物光谱的水体总氮估测

利用再生水补充城市湿地是目前湿地恢复与重建的主要方向,然而再水中高浓度的氮、磷含量极易导致水体富营养化。遥感技术已成为富营养化监测的重要手段,但对于植被覆盖水域的富营养化直接探测存在一定的局限性。以北京市典型再生水补水湿地奥林匹克公园南园湿地为研究区,利用湿地植物光谱进行水体富营养化主控因子总氮的遥感探测。测定芦苇(Phragmites australis)和香蒲(Typha angustifolia)的叶片光谱及水体总氮含量,在对数据进行预处理的基础上建立二者的关系模型,包括单变量模型(比值光谱指数(SR)模型和归一化差值光谱指数(ND)模型),与多变量模型(逐步多元线性回归(SMLR)模型和偏最小二乘回归(PLSR)模型),并利用交叉验证决定系数(R2cv)和均方根误差(RMSEcv)进行模型精度检验。结果表明,不同回归模型相比,多变量回归模型精度较高;多变量回归模型中,PLSR模型精度较高,R2cv可达0.72,RMSEcv仅为0.24,是建立湿地植物光谱与水体总氮含量关系的最优模型。不同湿地植物类型相比,利用芦苇反射光谱建立的各种预测模型的精度都高于香蒲。其他环境因子(总磷)也是影响TN含量与湿地植物反射光谱关系的重要因素。研究成果可以弥补现有水体富营养化遥感探测的不足,并为再生水利用的城市湿地水质监测与管理提供有力的科学依据。     

A Novel Dual-Compartment,Continuous-Flow Wetland Microcosm to Assess Cis-Dichloroethene Removal from the Rhizosphere

The anaerobic biodegradation of tetrachloroethene commonly results in the accumulation of chlorinated intermediates such as cis-1,2-dichloroethene (cDCE). Frequently, groundwater contaminated with chlorinated ethenes discharges to natural wetlands. The goal of this study was to quantitatively evaluate the effects of wetland plants and microorganisms on the fate of cDCE in the wetland rhizosphere. To accomplish this goal, a novel dual-compartment wetland microcosm was designed. A Phragmites australis individual was maintained in the microcosm, which was operated with continuous flows of air and mineral medium through the foliar and rhizosphere compartments, respectively, to incorporate mass transfer/transport processes that are important in natural wetlands and allow steady-state assessment of changes in dissolved O₂ and cDCE or [1,2–¹⁴C]cDCE levels. Substantial amounts of [¹⁴C]cDCE were phytovolatilized through a healthy P. australis individual to the foliar chamber. Rhizodegradation by native microorganisms associated with P. australis roots also converted substantial amounts of [¹⁴C]cDCE to ¹⁴C-labeled CO₂ and non-volatile compounds, presumably through cometabolic reactions that could be enhanced by the release of O₂ and exudates by P. australis. These results suggest that, in some cases, the intrinsic capacity of native wetland plants and microorganisms to remove cDCE from the rhizosphere may be substantial.