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1.
蓄水初期三峡水库草堂河水-气界面CO2和CH4通量日变化特征及其影响因素 总被引:1,自引:0,他引:1
为查明三峡水库蓄水初期典型支流水-气界面CO_2和CH_4通量的日变化特征,采用LGR在线分析仪-通量箱法,于2015年9月初在库腹一级支流草堂河回水区开展连续24 h的定位观测.结果表明,24 h监测期内,支流库湾水-气界面CO_2通量变幅为-81.642~180.991 mg/(m~2·h),呈"昼吸夜放"特征,均值为17.346 mg/(m~2·h),总体为释放特征;CH_4全天均表现为释放状态,释放通量均值为0.064 mg/(m~2·h),呈"昼弱夜强"变化.相关分析结果表明,CH_4和CO_2释放通量与风速呈正相关,与表层水温、溶解氧浓度、叶绿素a浓度呈负相关,说明风速物理扰动、浮游植物光合作用是控制草堂河水-气界面气体通量最重要的环境因素.同时,干-支流相互作用形成的特殊水环境(如异重流、水温分层)也与水-气界面温室气体通量过程密切相关,但是其作用机制更为复杂,应开展进一步系统观测和深入研究. 相似文献
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富营养化湖泊夏季表层水体温室气体浓度及其影响因素 总被引:6,自引:5,他引:1
为研究富营养化湖泊水体温室气体浓度及其影响因素,以太湖西岸和竺山湾为例,共调查研究了27个点位,采用顶空平衡法对其表层水体中溶解的甲烷(CH_4)和氧化亚氮(N_2O)浓度进行测定.结果表明,太湖近岸带蓝藻水华堆积区表层水体中CH_4和N_2O两种温室气体浓度远远高于开阔湖区点位,CH_4和N_2O最高浓度分别为3.79±0.095和0.078±0.003μmol/L.蓝藻水华堆积区和开阔湖区CH_4平均浓度分别为2.33±1.46和0.14±0.059μmol/L,N_2O的平均浓度分别为0.054±0.024和0.023±0.012μmol/L.两种气体在水中均呈现过饱和状态,其中蓝藻水华堆积区表层水体中CH_4和N_2O饱和度远远高于开阔湖区点位.此外,入湖河流河口区域表层水体溶解性N_2O浓度较高.将水中CH_4和N_2O浓度与水体环境因子之间进行相关性分析,表明水体总氮、总磷、铵态氮和溶解性有机碳浓度与CH_4和N_2O浓度呈显著正相关,CH_4浓度与硝态氮浓度呈显著负相关.研究结果揭示了太湖蓝藻水华堆积区是CH_4和N_2O两种温室气体重要的潜在排放源,蓝藻水华暴发对湖泊温室气体的排放具有重要影响,但该过程的驱动机制及影响因素仍需要进一步研究. 相似文献
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为了解东平湖菹草(Potamogeton crispus)腐烂分解对水体温室气体溶存浓度和界面扩散通量的影响,于2016年5-7月在东平湖菹草腐烂期采集上覆水和沉积物柱样,测定上覆水和孔隙水中温室气体(N_2O、CH_4和CO_2)的溶存浓度,采用Fick第一定律和双层模型计算沉积物-水-气界面扩散通量,同时分析上覆水和沉积物的理化性质,并采用网袋分解法于现场进行菹草腐烂分解试验,以探究东平湖菹草腐烂过程中温室气体溶存和扩散的主要影响因子及其主要来源.结果表明,菹草腐烂符合二次指数模型,分为快速衰减和慢速分解两个阶段;菹草腐烂过程中上覆水pH和亚硝态氮浓度表现为先降低后升高,而溶解氧、氨氮、硝态氮和可溶性正磷酸盐浓度则为先升高后下降,沉积物中铵态氮含量表现为先升高后降低,硝态氮为先降低后显著升高,有机质和p H呈降低-升高-降低的波动变化;上覆水中各温室气体浓度和水气界面扩散通量均表现为CO_2 CH_4 N_2O,其扩散通量分别为5862.9±5441.4、31.15±41.3和0.15±0.57μmol/(m~2·h),整体表现为大气温室气体的"源",并以碳排放为主;上覆水中N_2O浓度和水-气界面扩散通量均先降低后升高,孔隙水中N_2O浓度在快速和慢速分解阶段分别出现极大值(22.7和55.6 nmol/L),而其沉积物-水界面通量前期持续增加至腐烂结束后迅速降低;上覆水和孔隙水中CH_4浓度及其各界面通量均表现为前期略有降低后持续升高;上覆水中CO_2浓度和水-气界面通量表现为持续升高后降低并趋于稳定,而孔隙水中CO_2呈波动变化,在菹草腐烂初期向孔隙水扩散,后期向上覆水扩散.水温是影响上覆水中温室气体浓度和水-气界面通量的主要因素;沉积物是水体N_2O和CH_4的主要来源,孔隙水中浓度是控制其沉积物-水界面扩散的重要因素;而上覆水中CO_2呈现多源性,但以上覆水中有机物质的矿化为主. 相似文献
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水库是大气甲烷(CH4)的重要来源之一,但目前对水库(尤其是河道型水库)中溶解CH_4浓度及释放潜力的空间异质性的认识仍不足.为揭示河道型水库冬季溶解CH_4浓度的分布规律,于2020年1月在湖北宜昌黄柏河流域内西北口水库采用自主研发的新型快速水—气平衡装置(FaRAGE)连接便携式温室气体分析仪,开展了水体溶解CH4浓度的连续走航式监测及断面垂向监测.根据溶解CH4从库尾至库首的浓度变化可以将水库分为3段:距回水末端1 km内为快速降低段,溶解CH4浓度范围为0.117~0.233 μmol/L;1~6 km内为缓慢降低段,CH4浓度范围为0.055~0.117 μmol/L;6~13km范围内为浓度平稳段,CH4浓度范围为0.039~0.080 μmd/L.整体上,水库表层水体溶解CH_4浓度与表层水温、水深及距回水末端的距离呈显著负相关关系(r=-0.77、-0.89、-0.81;P0.01),与叶绿素a浓度、溶解氧浓度呈显著正相关性(r=0.95、0.97;P0.01).基于当月平均风速,采用薄边界层法估算了上述3段区域的DH_4扩散通量,分别为(0.023±0.004)、(0.012±0.003)、(0.007±0.001) mg/(m~2·h).西北口水库在冬季表现为向大气释放CH_4的"源",且由于溶解CH_4浓度分布不均而表现出较强的空间差异性. 相似文献
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于2014年4、7和10月以及2015年1月(分别代表春、夏、秋和冬季)对鄱阳湖13个常规监测点表层水体中氧化亚氮(N_2O)浓度进行测定,并选择合适的模型估算其释放量.结果表明,鄱阳湖全年N_2O平均浓度为32.57±17.35 nmol/L,总体处于过饱和状态,平均饱和度为256.83%±129.05%.鄱阳湖N_2O年平均交换通量为0.83±0.69μmol/(m2·h).鄱阳湖水体N_2O季节性释放规律为春季最高,平均交换通量为1.71μmol/(m2·h),其次是夏季和冬季,秋季最低.从空间上来看,春季北部湖区交换通量显著高于南部湖区.相关性分析表明,铵态氮浓度是影响夏季和冬季鄱阳湖水体N_2O产生的主要因素.结合水域面积初步估算出全年释放N_2O约1.29×107mol,其中春季和夏季是鄱阳湖水体N_2O释放的高峰期,总释放量约占全年的80.40%.全年通过N_2O输出氮素约为361.93 t,对鄱阳湖流域内N_2O分布及质量平衡具有一定影响. 相似文献
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植被类型及淹水带来的干湿交替过程是影响温室气体排放的重要因素.本文通过原状土柱模拟实验,模拟西洞庭湖水文节律变化对不同土壤—植被系统温室气体排放的影响.利用静态箱—气相色谱法研究不同植被—土壤类型(芦苇湿地、灰化苔草湿地和刚砍伐的杨树林湿地)在季节性淹水条件下的CO_2、CH_4和N_2O的排放通量变化,并探讨了在水位变化的情况下,不同植被—土壤类型对全球增温潜势的贡献.结果表明:在不同的水文条件下,芦苇湿地的CO_2排放通量均显著高于苔草和杨树林湿地;淹水过程导致3种植被类型覆盖湿地CO_2排放通量显著降低,甲烷排放通量升高,其中芦苇湿地CH_4排放通量升高显著,苔草和杨树林湿地CH_4排放通量升高不明显;水文变化及植被类型对N_2O排放通量的影响不显著;不同植被类型湿地对全球增温潜势的贡献为:芦苇杨树林苔草,分别为16191.3、3405.6和1883.1 kg/hm~2.本研究结果表明在西洞庭湖湿地恢复过程中,不再人为增大芦苇湿地面积,将杨树林湿地恢复为苔草湿地,更有利于降低湿地恢复过程中温室气体的排放. 相似文献
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河流是连接大陆和海洋两大碳库的桥梁,在全球碳循环中的作用举足轻重.金沙江作为长江的上游段,对区域碳循环及区域化学风化的影响非常重要.于2015年8月8-18日对金沙江下游水-气界面CO_2与CH_4通量特征进行监测与分析.采用顶空平衡法结合薄边界层模型估算法计算表层水体CO_2与CH_4的分压以及水-气界面的交换通量,并分析环境变量与其之间的相关性.研究发现,金沙江下游表层水体p(CO_2)平均值为2724.84±477.18μatm,表层水体p(CH_4)平均值为59.96±6.74μatm;水-气界面CO_2通量平均值为2.24±0.50 mmol/(m2·h),CH_4通量平均值为0.000163±0.00009 mmol/(m2·h),通量与分压趋势基本保持一致.表层水体p(CO_2)与溶解性无机碳浓度、碱度均呈显著正相关,而p(CH_4)与水温、叶绿素a浓度均呈显著正相关,CO_2通量与p(CO_2)、溶解性无机碳浓度、碱度均呈正相关,CH_4通量与p(CH_4)、风速均呈正相关,其他环境因素对通量的影响不明显,仍需进一步研究.金沙江下游水-气界面CH_4扩散通量较低,而CO_2扩散通量在世界主要河流中属于中等水平. 相似文献
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固定化氮循环细菌修复城市湖泊水体脱氮效果及N2O排放 总被引:4,自引:0,他引:4
利用从镇江金山湖天然水体中筛选分离出的土著氨化、亚硝化、硝化和反硝化细菌,将氮循环细菌固定化后在金山湖示范工程区进行水体脱氮净化效果研究.结果表明,运行一段时间后水质明显得到改善,氨氮、亚硝酸盐氮、硝酸盐氮以及总氮浓度均显著下降,氨氮浓度指标达到国家水质Ⅰ类标准,总氮浓度指标达到水质Ⅱ类标准.同时,对湖泊水体的N_2O气体排放通量进行了检测,结果显示,随着实验的进行,金山湖区的N_2O气体排放通量逐渐升高,4月份的平均值为23,51μg/(m~2·h)、5月份的平均值为29.52μg/(m~2·h)、6月份的平均值为59.10μg/(m~2·h).水质氮素指标以及N_2O气体排放通量数据说明利用微生物固定化载体强化净化技术对城市湖泊水质净化具有显著效果和重要意义. 相似文献
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滇西地区断层气体成因研究 总被引:10,自引:0,他引:10
本文讨论了滇西地区由温泉释放的断层气体中各主要组分(He、H_2、Ar、N_2、CO_2、CH_4、Hg)的分布特征及其成因机制。 作者指出,滇西地区断层气体中直接来自地幔的He是微不足道的,较高水平的He释放(>100ppm)可能直接来自地层中的火成岩;H_2的释放与地层岩性无关,而与深大断裂的活动或地震活动有成因联系;洱源地区九台等泉点中CH_4含量达2—3%,同位素测定表明,它是典型的无机成因,是该区深部热动力变质作用的产物;滇西地区断层气体中Hg的分布特征表明,并不是所有的活动性断裂都有高含量的Hg释放。具有较高含量的幔源CO_2和Hg释放是红河断裂的两个最重要的地球化学特征。 相似文献
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双碳”背景下,我国能源结构面临持续转型发展。作为清洁可再生能源,水电开发是近年来长江上游水资源开发利用的重点工作。然而,筑坝蓄水将在一定程度上改变区域碳排放情况。评估水库碳排放量是客观、科学认识水电清洁能源属性的基础,是国家温室气体清单的一个重要组成部分。基于IPCC国家温室气体清单指南层级1(Tier 1)的方法,以长江上游24个中、大型水库为案例,探讨长江上游典型水库生命周期内的碳排放量,并通过蒙特卡洛模拟对估算结果进行不确定性分析及模型参数的敏感性分析。结果显示,24个水库的生命周期碳排放量分布在0.0342~140.59 Tg CO2eq的区间内,总排放量达到264.05 Tg CO2eq(其中,CO2排放量占9.12%,CH4排放量占90.88%),单位发电量的碳排放均值为3.30 g CO2eq/(kW·h)(0.01~17.64 g CO2eq/(kW·h)),最小、最大值分别出现在锦屏二级水库和彭水水库。此外,敏感性分析发现,在模型涉及的参... 相似文献
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M. N. French R. L. Bras W. F. Krajewski 《Stochastic Environmental Research and Risk Assessment (SERRA)》1992,6(1):27-45
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. 相似文献
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Gtz Schroth Luciana Ferreira Da Silva Marc‐Andree Wolf Wenceslau Geraldes Teixeira Wolfgang Zech 《水文研究》1999,13(10):1423-1436
The partitioning of rain water into throughfall, stemflow and interception loss when passing through plant canopies depends on properties of the respective plant species, such as leaf area and branch angles. In heterogeneous vegetation, such as tropical forest or polycultural systems, the presence of different plant species may consequently result in a mosaic of situations with respect to quantity and quality of water inputs into the soil. As these processes influence not only the water availability for the plants, but also water infiltration and nutrient leaching, the understanding of plant effects on the repartitioning of rain water may help in the optimization of land use systems and management practices. We measured throughfall and stemflow in a perennial polyculture (multi‐strata agroforestry), monocultures of peach palm (Bactris gasipaes) for fruit and for palmito, a monoculture of cupuaçu (Theobroma grandiflorum), spontaneous fallow and primary forest during one year in central Amazonia, Brazil. The effect on rain water partitioning was measured separately for four useful tree species in the polyculture and for two tree species in the primary forest. Throughfall at two stem distances, and stemflow, differed significantly between tree species, resulting in pronounced spatial patterns of water input into the soil in the polyculture system. For two tree species, peach palm for fruit (Bactris gasipaes) and Brazil nut trees (Bertholletia excelsa), the water input into the soil near the stem was significantly higher than the open‐area rainfall. This could lead to increased nutrient leaching when fertilizer is applied close to the stem of these trees. In the primary forest, such spatial patterns could also be detected, with significantly higher water input near a palm (Oenocarpus bacaba) than near a dicotyledonous tree species (Eschweilera sp.). Interception losses were 6·4% in the polyculture, 13·9 and 12·3% in the peach palm monocultures for fruit and for palmito, respectively, 0·5% in the cupuaçu monoculture and 3·1% in the fallow. With more than 20% of the open‐area rainfall, the highest stemflow contributions to the water input into the soil were measured in the palm monocultures and in the fallow. Copyright © 1999 John Wiley & Sons, Ltd. 相似文献
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M. A. Kahn 《洁净——土壤、空气、水》2000,28(2):95-101
Red tide, a recurrent phenomenon has become conspicuous in several Kashmir lake ecosystems since 1991. The responsible organism (Euglena pedunculata), a rare flagellate rediscovered in the Kashmir Himalaya (Khan 1993) caused first and unprecedented red tide outbreak, constituting a maximum of 96% of resident numerical phytoplankton density in Dal Lake. At present, conflicting hypotheses exist on the generation of causal assemblage(s) imparting redness to waters: Jeeji Bai (1991) linked its origin to acid precipitation – a fallout of burning oil‐fields during the Gulf War – whilst Khan (1993) holds local factor(s) responsible. Field/experimental studies support the latter contention that the influx of untreated sewage, in unison with warm temperatures, high levels of PhAR, iron and interruption to hydrological flow‐pattern together with absence/or reduction in grazing activity created conducive environmental milieu for red tide outbreak. Dal Lake “red tide” drifted the bloom‐inoculum to other waters, including Lake Wular, where additional ecological niches were carved out, threatening the aesthetic value and biological diversity of Kashmir lakes. Ecological monitoring indicates frequent seasonal red tide occurrence in Dal Lake (including summer‐autumn event of 1998) which testifies its unabated eutrophication status. Further studies are needed on ecological adaptability and biogeographic distribution of this rare and unique red tide‐causing flagellate. 相似文献