DIATOM COMMUNITY SUCCESSION AND NUTRIENT EVOLUTION RECORDED FROM A SEDIMENT CORE OF THE LONGGAN LAKE, A LARGE SHALLOW LAKE IN EAST CHINA

The Longgan Lake is a shallow mesotrophic macrophyte-dominated lake. According to the high-resolution diatom research from its sediment core, the diatom community succession was built, and the total phosphorus (TP) and chlorophyll-a (Chl-a) concentration were quantitatively reconstructed for the past 2000 years, based on the diatom-TP and diatom-Chla transfer functions. The shifts of diatom assemblages also mirrored the developments of aquatic plant, reflecting the characters of aquatic ecosystem evolution. The inferred epilimnetic TP concentration fluctuated within a small range of 36 to 62μg/L, indicating the lake remained a relative stable mesotrophic status in the long historical period. The periodical variations of the diatom assemblage and trophic status suggest a mitigating function of shallow macrophyte-dominated lakes to nutrient input. The changes of lakes’ trophic status don’t linearly respond to the human disturbance in the catchment. The dynamics mechanism of phosphorus in macrophyte-dominated lakes, as inferred from diatoms, will provide a scientific foundation for the prediction of trophic status change in a shallow lake, as well as the lake ecological restoration and management decisions.

Temporal and Spatial Distribution of Elements in a Small Catchment, and Buffer Function of Wetland in Longgan Lake, China

Wetland is the conjunction of lake and terrene where human activities are concentrated. From the viewpoints of material transport and cycling in the terrene-lake system, wetland is the buffer where sand and mud, heavy metals, pollutants and nutrients are tarried. In this paper, we provide a case study based on the temporal and spatial distribution of elements in the Wangling River catchment, a small sub-catchment of Longgan Lake in the middle reaches of the Yangtze River. We have found that wetland can buffer major heavy metals such as Cr, Cu, etc. significantly, but has a little buffer function to some active elements such as Fe and Mn, which are always transported as solutions. Human activities not only influence the distribution of elements, but also weaken the buffer function of wetland. Intensive human activities in the Longgan Lake area in the past 70 years have been recorded in stream, wetland and lake sediments, especially the human activity events such as deforesting and reclaiming on a large scale in 1958 and the 1980’s. Human activities caused the increase of sedimentation rates since the 1950’s, as well as the increase of elements’ concentrations. The extensive use of fertilizers and pesticides since the 1960’s have led to the increase of total P concentrations. Increasing SO-2 emission accelerate the process of cation exchange in soil, and enhance the leaching of Mn out of soils. Permanent storing of water causes the soil gleyification that also intensifies the leaching of Mn. These are two major reasons for the obvious increase of manganese concentrations in recent 20 years in Longgan Lake. Intensive human activities since the 1950s’ have intensified the population in this region and thus destroyed the buffer function of wetland.

Lacustrine environment responses to human activities in the past 300 years in Longgan Lake catchment, southeast China

The chronology of a gravity core sediment from Longgan Lake center was defined by 210Pb, combining with historic events recorded by document and sediment. The relationship between vegetation, soil erosion and lake nutrient state was discussed based on pollen, magnetic parameters, diatoms, phosphorus and pigments. The results show that the lake has undergone twice obvious transformations from oligotrophic to mesotrophic condition. Two eutrophications occurring at about 1768AD and the beginning of the 20th century respectively were related to external nutrient loading increase resulting from the enhanced human activities in the lake catchment. It is probable that strength of human actions in historic periods was influenced more or less by climatic changes. The lake eutrophication presented a more serious tendency because of the wide use of chemical fertilizer, reclamation of wetland and wetland vegetation destruction around the lake in the last 40 years.

Geochronology of recent lake sediments from Longgan Lake,middle reach of the Yangtze River,influenced by disturbance of human activities

The impacts of human activities in Longgan Lake region on the distribution of 210Pb in lake sediment made it difficult to establish geochronological sequence. However, environmental proxies recorded these human activities and could be used as time marker to check 210Pb dating results. Based on the analysis of 210Pbexc distribution in cores LS-1 and LGL-1, and in combination with the human activities records in grain-size and element concentration, the sedimentation rates in the upper layers of these two cores were determined to be 0.19 and 0.23 cm/a respectively. The MAR (mass accumulation rates) of these two cores demonstrated that natural condition, such as precipitation and runoffs, led to the variation of MAR before human disturbance, and human activities controlled the sedimentary processes afterwards, which obviously reduced the particles influx into the lakes. During 1940s when human activity had not changed the water system within the catchment, 210Pb activity was abnormally strong in lakes along middle to lower reaches of the Yangtze River, which might be attributed to less precipitation and can be used as a time marker for geochronological research.

Study on the nutrient evolution and its controlling factors of Longgan Lake for the last 200 years

Based on the total phosphorous (TP) concentration in sediment core, the TP concentration in lake water quantitatively reconstructed from fossil diatoms and diatom-TP transfer function in the Longgan Lake during the last 200 years, the temperature and precipitation data from meteorological observation for the last 50 years, the temperatures and precipitation sequences of climate simulation for the last 200 years, as well as the amount of the agricultural phosphate fertilizer in Longgan area for nearly 50 years, the characteristic and the law of the nutrient status evolution were analyzed, and the influence of the climatic factor, the anthropologic factor and the aquatic biology factor on the nutrient status evolution and its mechanism were discussed for the Longgan Lake during the last 200 years. The results showed that, in the nearly 200 years, the TP concentration in the sediment core of the Longgan Lake gradually increased, its range of variation was situated between 330-580 mg/kg, the mean value was 388 mg/kg, a nearly 30-year vibration adjustment period existed at 1950 around. The TP concentration in lake water changed in a different way. Before 1950, it had a slow increasing tendency in fluctuated background, to 1950 around it reached up to the mean value (52.18 μg/L), and vibrated and adjusted around the mean value, then it fast declined, its change range was situated between 37.75-62.33 μg/L. The analyses indicated that, in the centennial time scale, the climate change was the main controlling factor, while in the decadal time scale in the recent 50 years, human activities were the leading factors for the nutrient status evolution of the Longgan Lake. 60% of the variability of the TP concentration in the sediments and 57% of that in lake water were due to human activities. The differentiation between phosphorus concentration in the sediment and in the lake water reflected the response processes and the adjustment abilities of the lake aquatic ecosystems to the lake nutrient level, implying the maintenance and the destruction of the balances between the algae and the aquatic plants, as well as the corresponding accumulating characteristics of the phosphorus.

长江中游2个湖泊沉积物枝角类微化石密度的垂直变化

为了重现湖泊枝角类的群落演替历史,反映人类活动对湖泊生态的干扰强度,选择长江中游的龙感湖和武昌湖分别设置2个和1个采样点,每个样点采集2根沉积柱,鉴定沉积物中的枝角类卵鞍和象鼻溞属壳刺并计数,测定沉积物样品的总氮和总磷含量并鉴定沉积物年代,探究枝角类微化石组成、密度垂直变化及其人类活动的影响。结果显示,在龙感湖和武昌湖沉积物中,分别鉴定出9种和12种枝角类卵鞍。龙感湖沉积物中的枝角类总卵鞍密度(均以干重计)为2.27个/g,高于武昌湖1.63个/g;象鼻溞壳刺的平均密度459.40个/g,显著高于武昌湖1.52个/g。自20世纪60年代以来,武昌湖沉积物中枝角类的优势类群由裸腹溞属、尖额溞属种类向裸腹溞属、盘肠溞属种类转变;50年代以前,龙感湖枝角类卵鞍的优势种群为盘肠溞属种类,之后其优势类群由盘肠溞属、裸腹溞属种类向象鼻溞属种类转变。2个湖泊沉积物中枝角类卵鞍和象鼻溞壳刺密度的垂直变化与湖泊富养化过程及渔业养殖历史一致。研究表明,人类活动的干扰强度影响了长江中下游湖泊沉积物中枝角类微化石的组成和密度变化。

基于大型底栖动物完整性指数的龙感湖健康评价

龙感湖位于安徽省华阳河湖群自然保护区,生态价值突出,应用底栖动物完整性指数科学评价湖泊水生态健康可为湖泊保护和管理提供依据。根据2021年4月在安徽省龙感湖10个监测点的底栖动物数据,通过对20个候选生物指标进行分布范围、判别能力及相关性分析,筛选出总物种数、优势类群数量百分比、软体动物个体数百分比、敏感类群种类数、粘附者种类数共5个核心参数组成完整性指数评价体系,采用比值法统一生物参数的量纲,累加各生物参数分值得到B-IBI值,利用四等分法确定湖泊健康分级标准。结果表明;湖区10个监测点中的3个为健康、4个为亚健康、2个为一般、1个为较差,整体水生态健康状况不容乐观。龙感湖东南部为健康、鄂皖交界水域为亚健康、东北部为一般,龙感湖东北部健康状况差可能是因为该区域位于支流二郎河入湖口,二郎河水体携带的生活污水和磷矿污染物富集在底泥中,进而影响了底栖生物完整性。

龙感湖地区近3000年来的植被及其气候定量重建

本文依据龙感湖钻孔的孢粉及硅藻资料，探讨了该地区近３０００年来的植被发展及气候变化。通过数值分析方法，重建了年均温及年降水的时间序列。发现气候波动存在两个阶段（依１．５ｋａＢ．Ｐ．前后划分）、四个旋回（０．８ｋａ的准周期），两个突变事件（３ｋａＢ．Ｐ．前后的冷暖急剧变化及１ｋａＢ．Ｐ．的降温事件）。这些变化与敦德冰心及固城湖孢粉反映的气候波动有较好的一致性。

湖泊中有色可溶性物质对近紫外及蓝光衰减的影响

研究巢湖(藻型湖泊)和龙感湖(草型湖泊)的有色可溶性物质(CDOC)对近紫外及蓝光衰减的影响时发现:巢湖水体中可溶性有机碳含量比龙感湖大. 2个湖泊中来源不同的可溶性有机碳对光的吸收极其相似,只是在量上有差异. 在巢湖水体中,光的衰减曲线在355-400nm之间有一个峰,且Kd值较大,而在龙感湖水体中,光的衰减曲线在500nm以下时随着波长的递减而增加. 从CDOC对Kd的贡献来看,它们之间最大的相关是在355nm左右,这是悬浮质、叶绿素以及CDOC共同作用的结果.

近百年来龙感湖地区湖泊营养化过程

由于近年来社会经济的迅速发展,湖泊富营养化问题日趋严重,其中湿地的破坏是导致入湖营养盐增加的一个重要原因。对湿地变化与湖泊营养盐状况关系的分析是制定湖泊环境整治和生态修复的重要科学依据。湖泊沉积物含有丰富的生物和理化方面的信息,在缺乏长期湖泊监测记录的情况下,可以用来重建湖泊及其流域过去变化的历史。根据龙感湖表层沉积物210Pb活度比变化,分析了该地区近百年来沉积物中湿地花粉、总磷和磁性参数,探讨了湖泊营养化过程及机理。研究表明,龙感湖近百年来营养级的增加是与湿生植被的破坏密切相关。20世纪上半叶的湖泊富营养化响应于磁性参数指示的流域土壤侵蚀速率的增加,而20世纪70年代以来湖泊营养程度的加重则与龙感湖流域农业化肥的使用和湿地植被破坏而导致湿地功能减弱有关。龙感湖流域内人类对湖周滩地的改造,破坏了湿地植被,助长了入湖物质的增加,湖泊营养相对富集,最终导致水体富营养化发生。

龙感湖近百年来沉积物磷的时空分布特征及其人类活动影响

湖泊沉积物蓄积的磷在湖泊环境发生变化(如pH值、Eh改变)时,往往能释放到水体,形成湖泊内源释放,造成湖泊富营养化。因此了解湖泊沉积物磷的蓄积特征,对于湖泊环境的治理和保护有重要意义。通过长江中游龙感湖不同部位钻孔的^(210)Pb、沉积物磷和其他环境指标分析表明,近百年来东部湖区沉积速率明显大于西部湖区,北部湖区略大于南部湖区,人类活动在20世纪50年代后期主要通过修建水库和闸坝,改变龙感湖水系结构,也改变了龙感湖的物源供给,因而西部湖区沉积速率略有放缓,东部湖区变化不明显。龙感湖沉积物磷的浓度空间上表现为东部高于西部,这与不同物源磷的背景值相关,时间序列上近百年来呈上升趋势,上世纪50年代以来上升趋势更为明显。在确定沉积物磷背景值的基础上,由于人类活动导致的磷的增加量表明,20世纪50年代开始人类活动导致沉积物磷的增加量持续上升,20世纪70年代末开始增加幅度更大,这一特征与人类活动的方式有关。

龙感湖地区近3000年来的气候环境变迁

本文通过分析龙感湖沉积物中的色素、孢粉、硅藻研究结果，探讨该区近3000年来环境气候波动特点．结果表明：3200一2400aBP，色素含量较高，与温度条件较好有关．该带孢粉浓度也最高，阔叶乔木树种花粉丰富，湿生及水生植物经常出现．总体上为相对暖湿阶段，其中仍有凉湿波动．2400－1600aBP，具体分为两个阶段，前期约2400－2000aBP．CD、TC、Myx含量明显较低，水生、湿生草本减少，气候偏凉干；后期各种色素含量均升高，与暧性木本属种增多相对应．表明气温有升高趋势．这一时期色素总体含量较上一阶段略低，与孢粉组合反映的气候温凉略湿特征一致．1600－1500aBP，该段CD、TC、Osc、Mry均为谷值．反映湖泊生物量减少，富营养化程度低，对比孢粉曲线其木本为谷值段，以禾本科为主，气候上反映为明显的降温事件．1500－1100aBP，CD、NC、TC、Osc及Myx含量均明显增大．湖泊生产力有所提高，反映了此时期气候好转，这也与孢粉资料吻合．1100－100aBP，整个阶段色素含量低，达到整个剖面的最低段．湖泊富营养化程度低，水质好转．而孢粉资料表明此阶段孢粉浓度低，针叶花粉增多，反映气温低，植被不发育，与色素结果对比较好．时段上相当小冰期．100aBP至今，各项色素含量明显增高，一方面反映湖泊的水体?

龙感湖水生植被

于1993年9月对龙感湖水生植被及环境进行了调查研究。龙感湖有水生植物26科38属50种,依据优势种群划分9个群丛,其分布面积283.5km^2,占全湖总面积的89.7％,植被现有年生产力达2147730t,对渔业生产和生态环境具有十分重要的意义。建议对该湖植被应合理开发利用,如果围网养鱼得到广泛地发展,渔业生产潜力每年可达4181.8t。

龙感湖钻孔揭示的末次盛冰期以来的环境演化

通过龙感湖滩地钻孔 2 4 .4m深度以内的沉积物岩性、生物和物理指标分析 ,在14 C年代测定的基础上 ,对龙感湖末次盛冰期以来的环境演化进行了恢复 .15 .0kaBP前和 10 .0 -6 3kaBP ,龙感湖区发育河流沉积 ,以低生物量和高磁化率为特征 ;约 15 .0 - 10 .0kaBP期间的晚冰期 ,龙感湖首次成湖 ,湖泊中生物量明显提高 ;现代龙感湖雏形始于约 6 .3kaBP后 ,至 3.7kaBP后发展为稳定的湖泊环境 .此外 ,花粉结果显示 ,龙感湖湿地植被大致形成于 3.3kaBP后 .然而 ,龙感湖的成因和演化 ,及其与长江关系的研究 。

长江下游湖泊中可溶性有机碳的时空分布

20 0 1年 7月至 2 0 0 3年 1月对长江下游的太湖、巢湖和龙感湖水体中可溶性有机碳 ( DOC)的时空分布进行了研究。结果显示 ,太湖水体中 DOC的平均浓度最高 ,巢湖次之 ,龙感湖最低 ;秋季水体中的 DOC浓度较冬季高 ;藻型湖泊水体中 DOC浓度较草型湖泊高 ;下午水体中 DOC的浓度较上午高。水体中 DOC浓度的垂直分布无明显的规律性。从周年来看 。

龙感湖稀土元素的地球化学特征

采用液．液萃取法，连续提取法和ICP-MS测试技术，对龙感湖不同季节水和颗粒物中稀土元素进行研究。结果表明，龙感湖的溶解态稀士含量极低，稀士总含量（EREE）在35．14—129．81ng／kg之间，且季节性变化明显。龙感湖溶解态稀土元素表现出平坦型的页岩配分模式，这是由于在草型湖泊中溶解态稀土主要以吸附在微细胶体上的形式存在，水粒相互作用在这个过程中起主要控制作用。悬浮物中的稀土含量顺序为：残渣态〉〉Fe—Mn结合态〉〉有机态和AEC态，颗粒物中稀土元素主要以残渣态形式存在。Fe—Mn结合态、有机态和AEC态的页岩配分模式为中稀士富集，残渣态的页岩配分模式为平坦型。这说明中稀土与轻重稀士相比具有更强的潜在地球化学活性，但在龙感湖的环境中的迁移能力相对轻重稀土来说较弱。

长江中下游湖泊沉积物生物可利用磷分布特征

利用化学提取方法对太湖6个样点,巢湖4个样点和龙感湖3个样点的表层沉积物和沉积物柱样进行了生物可利用磷(BAP)测定．北太湖表层沉积物的平均含量为259．5mg／kg,而西部湖区平均含量为114 6mg／kg,湖心区平均含量为40．6 mg/kg,而东太湖平均含量为50．7 mg／kg,呈显著北高南低的特点．巢湖西部湖区表层沉积物的BAP平均含量为 254．2 mg／kg,而东部湖区BAP含量降低为101．9mg／kg．龙感湖表层沉积物BAP平均含量为67．8 mg／kg．显著表明污染程度较高的湖区沉积物的BAP相应较高．BAP在沉积物中随深度呈指数降低,显示生物可利用磷在沉积作用下向稳定的非活性磷转化．夏季沉积物中的BAP由于生物活性的增强向溶解态活性磷转化过程增强,显示为较低的BAP含量．BAP 含量与水体溶解态活性磷呈正相关关系,且该相关性在BAP含量较低的样点好于高BAP的样点．

龙感湖沉积物中人类活动导致的营养盐累积通量估算

通过LL-4孔沉积环境指标研究表明，近100年来龙感湖地区人类活动加强，导致营养元素磷、碳、氮以及铁在沉积物中的浓度均呈增长趋势，特别是1950年以来，随着大量人口的迁入，围湖造田、破坏湖滨湿地等造成水土流失加剧，沉积物质量累积速率加快，同时营养元素累积量急剧增加。根据营养元素与参比元素Al，Fe和Ti之间的关系，以及不同营养元素之间的相互关系，人类活动引起的累积量得以从自然背景上区分出来，结合沉积物质量累积速率计算，人类活动引起的磷、有机碳和氮的累积通量分别在151．0～889．4mg／m^2a，4．3—149．0g／m^2a和0．5～18．6g／m^2a间变化。碎屑物质的累积稀释了沉积物中营养盐的富集浓度，龙感湖草型湖泊的特点，使湖泊沉积环境易于呈氧化环境，生物和地球化学作用，也削弱了人类活动累积营养盐的变化幅度，使沉积中营养盐呈平稳上升的趋势。

龙感湖沉积物碳、氮同位素记录的环境演化

通过对龙感湖沉积物样品中δ13Corg、δ15N、有机碳与总氮比值(C/N)、总有机碳(TOC)和总氮(TN)含量的测定,分析了自1948年以来龙感湖沉积物有机质的来源,探讨了湖泊生产力变化以及随后的沉积演化过程。结果表明:在这个沉积历史阶段中,湖泊沉积物有机质以自生有机物源为主,大型水草发育,伴有低等藻类参与,湖泊沉积物受陆源输入影响较小,基本不受城市污染物的输入影响,但受流域农业化肥大量使用的影响较大;随着营养物质的输入,湖泊的初级生产力逐渐增大,藻类开始发育;在沉积历史上L2点附近低等藻类相对发育早,但L1点沉积物相对能够固定更多的营养盐。