胶州湾大型底栖软体动物物种多样性研究

1998年2月至2004年11月,共7年27个航次对胶州湾10个站进行综合调查,研究了其大型底栖软体动物的多样性现状(菲律宾蛤仔(Ruditapesphilippinarum)除外)并探讨其成因。结果表明:在胶州湾共发现62种底栖软体动物,优势种是滑理蛤(Theoralubrica)和豆形胡桃蛤(Nuculafaba)。从1998年至2004年期间物种多样性指数(H′)年际间波动幅度不大,且无明显的规律性变化;但季节变化明显,秋季和冬季较高,春季和夏季较低。物种均匀度指数(J)则为秋季最高(0.87),夏季最低(0.58)。物种丰富度指数(D)除夏季相对较低(1.82)外,其他三个季节差别不大。     

长江口九段沙湿地大型底栖动物群落结构的季节变化规律

2004年11月至2005年10月,调查了长江口九段沙湿地大型底栖动物群落特征的季节变化及其土壤因子影响,共调查到大型底栖动物30种,主要由甲壳动物、环节动物、软体动物及昆虫幼体组成,光滑狭口螺(Stenothyra glabra)、堇拟沼螺(Assiminea violacea)、焦河蓝蛤 (Potamocorbula ustulata)、中国绿螂 (Glaucomya chinensis)和谭氏泥蟹(Ilyrplax deschampsi)为优势种,且生物密度四季变化明显.春季大型底栖动物生物密度和生物量处于最高水平,多样性指数最高.夏季密度和生物量最低,物种多样性也较低,分布较不均匀.秋、冬季生物种类数与生物量差异不显著,生物密度冬季较秋季高.春、夏、秋季底栖动物种类数、密度和生物量均未与土壤因子达到显著相关水平.冬季土壤湿度与有机质含量与底栖动物密度显著相关.     

胶州湾潮下带大型底栖动物群落的季节变化

胶州湾位于山东半岛南岸, 是黄海深入内陆的半封闭天然海湾, 底栖动物种类丰富。本文根据2014年2、5、8和11月4个航次(冬、春、夏、秋)的调查资料, 采用优势度指数, 物种多样性指数、丰富度指数、均匀度指数, Bray-Curtis相似性聚类和非参数多维标度排序(NMDS)方法, 分析了胶州湾大型底栖动物群落的季节变化特点。各航次共采集大型底栖动物199种, 其中多毛类79种, 甲壳动物47种, 软体动物40种, 棘皮动物17种, 其他类群16种。各季度优势种有变化亦有重叠, 以多毛类为主。2014年度胶州湾大型底栖动物的年平均丰度为209.85 ind./m², 最高丰度出现在秋季, 最低出现在春季; 年平均生物量为79.22 g/m², 最高生物量出现在夏季, 最低出现在春季。物种多样性指数(H')变化范围为2.16-2.86, 物种丰富度指数(D)变化范围为2.79-3.72, 物种均匀度指数(J)变化范围为0.58-0.82。聚类分析结果显示, 4个航次的群落相似性系数均较低, 分布格局存在季节性变化。近年来, 伴随海岸带开发及人类活动的持续影响, 胶州湾底栖生境的稳定性受到一定的威胁, 建议继续开展长期连续的监测, 探索有效的综合治理措施, 使胶州湾海洋生态系统能够持续健康的发展。     

温榆河大型底栖动物季节分布特征的研究

为了研究温榆河底栖动物季节变化情况,于2011年对温榆河大型底栖动物进行了季节采样,并采用物种优势度指数、Shannon-Wiener指数、Margalef指数、Pielou指数4个指标探求大型底栖动物季节分布特征。结果表明:温榆河共检出底栖动物64种,春季、夏季和秋季均有3种优势物种,其中,夏、秋两季的优势物种均为霍甫水丝蚓(Limnodrilus hoffmeisteri)、猛摇蚊(Chironomus acerbiphilus)和苏氏尾鳃蚓(Branchiura Sowerbyias)。生物多样性指数基本以秋季为最大值,秋季是评价研究区底栖动物群落的最佳季节。Pearson相关分析表明水温对春季生物多样性指数的影响最为显著,夏季和冬季均只有Pielou指数与其中的一个水质指标呈显著正相关关系。     

珠江口大型底栖动物的群落结构及影响因子研究

2008年8月至2009年5月, 调查了珠江口水域大型底栖动物季节分布以及与环境的关系, 结果表明:共鉴定出大型底栖动物34种, 多毛类和软体动物是该水域大型底栖动物的主要类群;大型底栖动物的密度和生物量以春季最高, 分别为759ind/m2和5.03g/m2,秋季则最低,分别为274ind/m2和2.34/g/m2.食底泥者是珠江口大型底栖动物最主要的功能摄食类群。研究区大型底栖动物的物种多样性指数(H′)、物种均匀度指数(J′)和物种丰富度指数(D)差异均不显著。典型对应分析表明:夏季锌、铜、铅、磷酸盐和透明度等5个因子与珠江口大型底栖动物群落相关性显著;秋季为铵氮;冬季和春季则分别为透明度和温度。       

珠海横琴红树林区不同季节大型底栖动物群落结构与分布

对珠海横琴岛沿岸次生红树林区大型底栖动物的群落结构与分布的季节性变化进行比较研究。采集到软体动物、甲壳动物、环节动物、昆虫和鱼类共39 种。大型底栖动物平均栖息密度为秋季最高(1872.53 ind·m^–2), 春季最低(401.60 ind·m^–2); 平均生物量也是秋季最高(155.66 g·m^–2), 夏季最低(24.43 g·m^–2)。各季节不同样地所采集的物种其栖息密度在100 ind·m^–2 以上。底内型(IN)及杂食性(O)物种分别超过动物总数的50%。系统聚类显示, 除冬季外, 老鼠簕和桐花树站位的相似性极低, 其余站位居于两者之间。Margalef 丰富度指数、Shannon-Wiener 多样性指数、Simpson多样性指数和Pielou 均匀度指数的综合分析表明, 本调查点大型底栖动物的群落结构、生物多样性等具有季节性的变化, 并已受到一定程度的人为干扰。     

长江口新生湿地大型底栖动物群落时空变化格局

为了解长江口新生湿地大型底栖动物时空变化格局,2004年11月—2005年10月对九段沙湿地的3个沙洲以及各主要生境进行了调查。结果表明:九段沙湿地大型底栖动物密度和生物量均呈春季最高,夏、秋季下降,秋季末和冬季回升的趋势,整体生物多样性水平较低,分布不均匀。夏季上沙和中沙底栖动物密度存在显著差异,四季生物密度和生物量空间梯度为下沙>上沙>中沙。由物种组成分析可知,九段沙湿地大型底栖动物群落时空变化与优势种的消长有关。各季海三棱藨草带和藨草带底栖动物密度和生物量最高,芦苇和互花米草次之,光滩区域最低,且群落季节波动大。外来物种互花米草生境下底栖动物群落特征与土著种芦苇生境下无显著差异。     

淮北煤矿区塌陷湖大型底栖动物群落结构及水质生物学评价

2013年对淮北采煤塌陷湖(乾隆湖和临涣湖)大型底栖动物群落结构进行了季节性调查。共采集到大型底栖动物26种, 隶属于3门5纲17科. 乾隆湖和临涣湖年平均密度分别为230.85和215.80 ind./m2, 年平均生物量分别为56.11和36.38 g/m2。两湖大型底栖动物以摇蚊幼虫、霍甫水丝蚓和苏氏尾鳃蚓为优势类群, 底栖动物最高密度均出现在夏季(乾隆湖为 278.0 ind./m2, 临涣湖为288.2 ind./m2); 生物量则主要以软体动物和水生昆虫为主, 夏季和秋季大型底栖动物生物量明显高于春季和冬季。运用Shannon多样性指数(H')、Margalef多样性指数(D)和Biotic Index生物学指数(BI)对乾隆湖和临涣湖进行水质生物评价研究, 结果显示Shannon多样性指数不适宜于该两湖的水质生物评价, BI的评价结果与水质状况基本相符。综合 Margalef多样性指数和BI生物指数评价的结果表明: 乾隆湖和临涣湖春季和冬季处于轻度污染状态, 夏季和秋季处于中度污染状态。     

珠江口及邻近海域大型底栖动物多样性随盐度、水深的变化趋势

利用2006年7-8月(夏季)、2007年4-5月(春季)和2007年10-12月(秋季)珠江丰水期、平水期和枯水期3个航次在南中国海北部珠江口附近海域4条由河口、近岸到深水区调查断面的数据, 研究大型底栖动物多样性由河口-近岸-深水的变化趋势及与环境因子的关系。春季、夏季和秋季分别获得大型底栖动物273、256和148种, 各季节均以环节动物种类最多, 节肢动物次之。大型底栖动物种类数、丰度、生物量和Shannon-Wiener多样性指数均由河口向近岸海域升高, 再由近岸向外海深水区降低。Pielou均匀度深水区最高, 其次为近岸。河口和深水区大型底栖动物k-优势度曲线位于近岸浅水域曲线之上, 表明生物多样性由河口向近岸升高, 而由近岸向深水则降低。大型底栖动物与环境因子Pearson相关性分析表明, 春、秋季大型底栖动物种类数、丰度和生物量与水深呈显著的负相关, 秋季种类多样性指数和均匀度也与水深呈显著的负相关性, 而夏季仅生物量与水深呈显著的负相关; 春、秋季大型底栖动物种类数、生物量、丰度、多样性指数和种类均匀度与盐度的相关性不显著, 但是夏季大型底栖动物种类数、丰度、多样性指数和种类均匀度与盐度呈显著正相关。单位面积(0.2 m²)内, 珠江口及邻近海域大型底栖动物在近岸浅水区较深水区和河口生物多样性高, 且生物量丰富。     

宁津近岸海域大型底栖动物生态学特征和季节变化

宁津海域位于山东半岛东端,南北黄海交界处. 根据2007年1、4、7及10月4个航次(冬、春、夏、秋)对宁津近岸海域大型底栖动物调查资料,采用优势度指数、物种多样性指数、丰富度指数、均匀度指数,Bray-Curtis相似性聚类分析以及MDS标序等方法,分析了该区域内大型底栖动物的生态学特点和季节变化.结果表明： 该区域共采集到大型底栖动物243种,其中多毛类动物96种;软体动物43种;甲壳动物77种;棘皮动物13种;其他类群动物14种.各季度优势种有变化也有重叠,拟特须虫和日本倍棘蛇尾为4个季度共有优势种.调查海域年平均生物量为9.5 g·m^-2,最高生物量出现在春季,最低出现在冬季;年平均丰度为219.6 ind·m^-2,最高丰度出现在冬季,最低出现在秋季.物种多样性指数(H)变化范围2.82～3.23,物种丰富度指数(D) 2.28～2.75,物种均匀度指数(J) 0.82～0.86.聚类分析结果表明,4个航次群落分布格局均包含近岸群落和远岸群落;大型底栖动物群落结构与水深和底质等环境因子密切相关.     

The biodiversity of macrobenthos from Jiaozhou Bay

The current situation of the animal species biodiversity of macrobenthic fauna in the Jiaozhou Bay (South Shandong Peninsula, Yellow Sea) is reported in the present paper, based on the data from 15 investigation cruises carried out from February 1998 to November 2001. In analyzing the data, the Shannon-Wiener index, and species evenness and richness indices were used to study the trends of variation of the community structure, the species assemblages in the macrobenthic community, the dominant species, and the abundance of macrobenthic fauna in Jiaozhou Bay. A total of 322 species of macrobenthic animals were found in the bay, of which 133 species belong to 44 families of Polychaeta, while 92 species belong to 42 families of Crustacea. The average number of species per sample station ranged from 8 to 26. The Shannon-Wiener indices were very different among the samples, with the highest being recorded from Station 8 in November 2001, and the lowest from Station 9 in August 2001. The number of species, the Shannon-Wiener indices, and the species richness indices from Stations 7 and 9 were generally lower than those from other stations. This is because both the stations are situated at areas with a strong current and where the sediment is coarse sand. Although the richness index of species and the Shannon-Wiener index were high in Station 3, the Pielou evenness index was the lowest of all the sampling stations. This is because the station is located near the culture area of Ruditapes philippinarum, where a high abundance of clams caused low evenness. The results also revealed that the number of species and abundance greatly affected the biodiversity, and some environmental factors such as temperature, salinity, and primary productivity were also closely interrelated with biodiversity. Pollution and overexploitation caused by human activities were very important factors affecting macrobenthic biodiversity. In order to find the best way to enhance and protect living marine resources, the relationship between human activities and the biodiversity of macrobenthos in the Jiaozhou Bay should be studied further.     

The biodiversity of macrobenthos from Jiaozhou Bay

The current situation of the animal species biodiversity of macrobenthic fauna in the Jiaozhou Bay (South Shandong Peninsula, Yellow Sea) is reported in the present paper, based on the data from 15 investigation cruises carried out from February 1998 to November 2001. In analyzing the data, the Shannon-Wiener index, and species evenness and richness indices were used to study the trends of variation of the community structure, the species assemblages in the macrobenthic community, the dominant species, and the abundance of macrobenthic fauna in Jiaozhou Bay. A total of 322 species of macrobenthic animals were found in the bay, of which 133 species belong to 44 families of Polychaeta, while 92 species belong to 42 families of Crustacea. The average number of species per sample station ranged from 8 to 26. The Shannon-Wiener indices were very different among the samples, with the highest being recorded from Station 8 in November 2001, and the lowest from Station 9 in August 2001. The number of species, the Shannon-Wiener indices, and the species richness indices from Stations 7 and 9 were generally lower than those from other stations. This is because both the stations are situated at areas with a strong current and where the sediment is coarse sand. Although the richness index of species and the Shannon-Wiener index were high in Station 3, the Pielou evenness index was the lowest of all the sampling stations. This is because the station is located near the culture area of Ruditapes philippinarum, where a high abundance of clams caused low evenness. The results also revealed that the number of species and abundance greatly affected the biodiversity, and some environmental factors such as temperature, salinity, and primary productivity were also closely interrelated with biodiversity. Pollution and overexploitation caused by human activities were very important factors affecting macrobenthic biodiversity. In order to find the best way to enhance and protect living marine resources, the relationship between human activities and the biodiversity of macrobenthos in the Jiaozhou Bay should be studied further.     

胶州湾西部海域大型底栖动物多样性的研究

为了揭示胶州湾最近几年底栖动物多样性的变化, 作者于2003年9月到2004年9月在胶洲湾西部海域5个测站每2个月1次共进行了7个航次采样, 以种类组成、生物量和栖息密度为基础, 对大型底栖动物多样性进行了分析。使用PRIMER软件计算得到以下变量: 群落的物种数(S)、丰富度(D)、Shannon-Wiener物种多样性指数(H')和均匀度指数(J')。结果表明: 位于大沽河口的D站和水道中央的S站的多样性最低; 养殖区内外站位的多样性差异显著; 丰度/生物量曲线表明, 养殖区内的底栖动物群落已经受到了一定程度的扰动。群落物种数(S)和丰富度(D)的季节性变化明显, 春季和秋季较低, 夏季和冬季较高。分析菲律宾蛤仔(Ruditapes philippinarum)增养殖区的站位(D)发现, 多样性指数和丰富度与次级生产力有着负相关的关系。物种多样性指数和丰度/生物量曲线的分析显示, 该研究海域处于一个轻度人为扰动的状态。     

山东半岛南部海湾底栖动物群落生态特征及其与水环境的关系

2006-2007年对山东半岛南部4个海湾(荣成湾、桑沟湾、靖海湾和五垒岛湾)19个站位的底栖动物群落结构特征进行了研究,并对14个环境因素和底栖动物群落生态特征分别进行主成分分析和Spearman相关分析。结果显示,荣成湾、桑沟湾和靖海湾的底栖动物种类中,多毛类所占比例最高,而五垒岛湾仅秋、冬季多毛类所占比例最高。根据聚类分析和非度量多维标度方法分析,4季底栖动物群落均可分为2个群落,春、冬季的第一聚群为靖海湾和五垒岛湾,第二聚群为荣成湾和桑沟湾。秋季荣成湾、桑沟湾、靖海湾组成第一聚群,第二聚群由五垒岛湾构成。夏季,底栖动物Shannon-Wiener多样性指数(H')与采样深度和总碱度呈显著正相关,与水温呈极显著的负相关关系。秋季,与硝酸盐呈负相关关系,说明富营养化对山东半岛南部4个海湾大型底栖动物群落产生了一定负面影响。ABC曲线法分析显示,荣成湾和桑沟湾底栖动物的丰度优势度曲线与生物量优势度曲线相交,表明荣成湾和桑沟湾大型底栖动物群落处于中度干扰状态,密集的养殖活动可能对其生态系统带来了巨大影响,加强海水养殖管理,强化生态健康养殖理念,合理利用海洋生物资源,对大型底栖动物群落的稳定性具有重要意义。     

胶州湾海域鱼类群落种类组成及多样性

为了解胶州湾海域鱼类群落结构特征,根据2016—2017年间对胶州湾海域进行的4个航次底拖网调查数据,采用相对重要性指数、生态多样性指数和典范对应分析(canonical correspondence analysis,CCA)、非线性多维标度排序(non-metric multidimensional scaling,NMDS)等方法分析了胶州湾海域鱼类群落的种类组成和多样性特征。结果表明:调查共采集到鱼类46种,隶属2纲10目30科41属,以硬骨鱼纲鱼类为主(45种,97.83%)。其中,鲈形目(Perciformes)最多(22种,47.83%),其次是鲉形目(Scorpaeniformes),占15.22%。种类数季节变化明显,以夏季最高,23种;秋季最低,16种。优势种组成以赤鼻棱鳀(Thryssa kammalensis)、褐菖鲉(Sebastiscus marmoratus)、褐牙鲆(Paralichthys olivaceus)、大泷六线鱼(Hexagrammos otakii)、许氏平鮋(Sebastes schlegeli)和矛尾鰕虎鱼(Chaeturichthys stigmatias)等鱼类为主。多样性分析显示,鱼类物种多样性存在明显的季节差异。多样性指数(H′)季节变化范围为1.668—2.453,以夏季最高,春季最低;均匀度指数(J′)季节变化范围为0.577—0.808,以秋季最高,春季最低;丰富度指数(D′)季节变化范围为2.431—3.123,以冬季最高,秋季最低。典范对应分析表明,水温、盐度、水深和pH是影响胶州湾海域鱼类群落物种组成的主要环境因子,且水温和pH是影响鱼类群落结构及多样性时空变化的主要因子。与历史调查资料相比,由于人类活动对胶州湾生态系统的干扰,鱼类群落结构发生了较大变化,优势种组成更替明显,多样性水平降低,鱼类群落结构趋向简单化。     

Community characteristics and of zooplankton in Qinzhou Bay

Qinzhou Bay, the biggest bay in Guangxi Province, is very species-rich and is developing a robust marine economy. In recent years, as human impact has increased, problems associated with the environment have become more complicated. Measuring zooplankton diversity and abundance is a way to monitor environmental conditions. According to the data from four ecological surveys of the zooplankton in Qinzhou Bay during 2008 and 2009, a total of 134 species of zooplankton were identified, including 52 Copepoda species, 27 Medusa species, 14 Planktonic larvae, 9 Chaetognatha species, 8 Pteropoda species, 5 Amphipoda species, 4 Cladocera species, 4 Ostracoda species, 3 Thaliacea species, 2 Appendiculata species, 2 Sergestdae species, 2 Protlsta species, 1 Rotiera species and 1 Cumacea species. The fauna was clearly characterized as tropical population. The total species number was highest in autumn, followed by spring, winter and summer. Zooplankton species diversity in Qinzhou Bay has increased compared with the results obtained in 1983–1985 (83 species). However, compared with other bays, the number of zooplankton species in Qinzhou Bay is close to Daya Bay (128), higher than in Zhilin Bay (60), Jiaozhou Bay (81) and Luoyuan Bay (70), and far lower than in the north South Sea (709). We adopted the dominant index Y > 0.02 as the distinguishing standard of dominant species. The number of dominant species in spring, summer, autumn and winter were six, nine, eight and five. There was only one common dominant species (Penilia avirostris) appeared in different seasons, For summer and autumn, the shared dominant species numbered about four. Between other seasons, the shared dominant species varied between two and three. The number of uniquely dominant species was four in summer, three in autumn and one in both spring and winter. The dominant species in different seasons have some overlaps and some differences. The average biomass of zooplankton was 378 mg/m³ at all times of year. The average biomass was largest in autumn, followed by winter, and was the least in spring and summer. The average density of zooplankton for the entire year was 805.11 ind/m³. The average density was largest in summer, followed by winter, and was least in autumn and spring. Copepoda and Planktonic larvae were the major components of zooplankton in spring and summer at Qinzhou Bay, with the other species’ densities under 10%. In autumn, Copepoda, Planktonic larvae and Chaetognatha were the major components of the biomass, and in winter, the major species were Copepoda and Cladocera, with the others species’ density under 10%. The average value of the Shannon–Wiener diversity index (H′) was 3.84 and the evenness index (J′) was 0.77. The zooplankton diversity index and community evenness overall were good and the community organization had a complete and stable state, but the status of the community was relatively weak. The relationship between biomass/density of zooplankton and environmental factors is remarkable. Biomass and density are positively correlated with temperature and nutrient concentration, and are negatively correlated with salinity.     

滆湖底栖动物群落的时空变化及水质生物学评价

2009年5月-2010年2月对滆湖底栖动物群落进行了调查,并根据底栖动物群落结构对水质进行了生物学评价。结果表明:采集到底栖动物共35种,隶属于3门25属;优势种类为中国长足摇蚊(Tanypus chinensis)、霍甫水丝蚓(Limnodrilus hoffmeisteri)、苏氏尾鳃蚓(Branchiura sowerbyi)、克拉泊水丝蚓(L.claparedeianus)、中华河蚓(Rhyacodrilussinicus);滆湖底栖动物的年均密度为374.1ind·m-2,寡毛类对密度的贡献最大,占年均密度的77.4%,最大密度出现在夏季,春季最低,St14年均密度高于其他站点;滆湖底栖动物的年均生物量为17.78g·m-2,软体动物对生物量的贡献最大,占年均生物量的97.4%,夏季生物量最大,冬季最低,St14年均生物量明显高于其他各个站点;底栖动物的密度和生物量随季节变化明显,密度的季节变化表现为夏季>秋季>春季>冬季,生物量变化表现为夏季>春季>秋季>冬季;Shannon-Wiener多样性指数值(H’)、Margalef多样性指数值(D)、Pielou均匀度指数值(J)和BI指数值表明滆湖水体处于中度到重度污染状态。     

庐山鸟类多样性及季节动态分析

2010年1月～2011年1月,采取样线法,共选取18条样线对庐山鸟类的多样性进行调查,共记录鸟类94种,隶属14目36科。其中留鸟60种,夏候鸟15种,冬候鸟16种,旅鸟3种。对不同季节的鸟类群落特征进行比较分析,从Shannon-Wiener指数看出,秋季多样性最高,为3.49;夏季次之,为3.44;冬季为3.40;春季为3.17。比较均匀性指数发现,秋季的均匀度最高,为0.51;冬季次之,为0.49,与前者仅有0.02的差距,可见二者丰富度差距很小;春季为0.41;夏季最低,仅有0.37,比较各季度的差距发现,最高的季度和最低的季度之间的差距为0.14。说明庐山鸟类的均匀度相差不大,庐山的鸟类群落均匀性在时间上无明显波动,相对稳定。     

珠江口近海浮游植物生态特征研究

1998～1999年对珠江口近海浮游植物进行了5个航次现场调查,共鉴定出浮游植物239种．其中。硅藻最多,占72．4％,甲藻次之,占23．8％,其他门类合占3．8％．种类组成以暖水种和广温种为主;优势种季节更替明显,四季的主要优势种依次为伏氏海毛藻(Thalassiothrix frauenfeldli)、柔弱菱形藻(Nitzschia delicatlssima)、伏氏海毛藻、细弱海链藻(Thalassiosira subtilis)．细胞密度全年变幅0．2×10^4～2767．1×10^4cell·m^-3,四季平均98．7×10^4cell·m^-3,夏、冬季明显高于春、秋季．平面分布呈近岸明显高于外海趋势。密集区终年出现在西北海域上川岛附近．Shannon—Wiener指数、Pielou均匀度和多样性阈值四季均值变幅分别为2．63～3．17、0．53～0．71和1．74～2．23,群落多样性水平较高,结构较稳定．