Rybinsk Reservoir(雷宾斯克水库)研究综述
Rybinsk Reservoir 雷宾斯克水库 - The long – term and seasonal dynamics of the water level in the Rybinsk reservoir during the period from 1947 to 2020 is considered. [1] The mass of pharyngeal teeth (pharyngeal jaws with teeth located on them) and its proportion of the total body mass of the roach Rutilus rutilus (Linnaeus, 1758) with different feed types in the Rybinsk Reservoir have been analyzed. [2] Larvae were maintained for 20 days, separately in two batches of natural bottom sediments sampled from Rybinsk Reservoir (Russia), each differing in PCB content (425. [3] New data on chlorophyll content at standard stations in the Rybinsk reservoir, that continue series of long-term observations, were obtained in May–October 2015–2019. [4] The purpose of our study was to study the vegetation cover of the mouth section of the small river Chesnava, flowing in the Nekouz and Breitovsky districts of the Yaroslavl region and flowing into the Rybinsk reservoir. [5] The key links of the food web—plankton, microperiphyton, detritus, and benthic invertebrates—were collected for stable isotope analysis of carbon (δ 13 C) and nitrogen (δ 15 N) after 20-day exposure in mesocosms simulating the conditions of the near-shore biotope of the Rybinsk Reservoir without cyanobacteria (variant I) and with high abundance of cyanobacteria (variant II). [6] All the studied rivers flow into the Rybinsk Reservoir and have different morphology of the studied estuaries. [7] Samples were collected in August 2015-2018 at 26 stations in three large reservoirs of the Upper Volga (56°51'-58°22'N, 35°55'-38°25'E): Ivankovo, Uglich and Rybinsk reservoirs. [8] — The paper reports the study of macroparasite load and aggressiveness of the European perch Perca fluviatilis juveniles of different size captured in the Rybinsk Reservoir (Volga River). [9] , 1758 from the Rybinsk Reservoir collected in 2016–2019. [10] The changes in the ratio of species representing different morpho-functional groups, identified by physiological, morphological and ecological parameters [29] were analyzed based on the study on phytoplankton in different reaches of the Rybinsk Reservoir in 2000–2005. [11] 0 μg/L), the reservoirs are classified as eutrophic; the Rybinsk Reservoir was classified as mesotrophic only in cool 2017 (10. [12] The authors present the results of satellite altimetry measurements calibration from the space geodetic system “GEO-IK-2” in the water area of the Rybinsk reservoir, obtained through two independent methods. [13] macrocotyle in zebra mussels discovered in Poland (Wigry Lake), Lithuania (Elektrenai Reservoir and Sirvinta River), Russia, Belarus (Lepelskoe Lake and Lukomskoe Lake), and in fish Leuciscus idus, Scardinius erythrophthalmus in Russia (Rybinsk Reservoir on the Volga River). [14] Most of the experiments were carried out on adult bream (Abramis brama L) from the Rybinsk Reservoir. [15] This study analyzes the inflow, runoff and water level of the Rybinsk Reservoir during the extremely highwater year of 2017. [16] A correlation analysis between chlorophyll a , nitrogen, and phosphorus compounds in Rybinsk Reservoir is carried out. [17] The data on seasonal and long-term dynamics of chlorophyll in plankton of the Rybinsk Reservoir (Upper Volga, Russia) obtained in May – October 2009–2019 at six standard stations using the fluorescence method are presented. [18] ) inhabiting the open pelagial of the Main reach and the river reaches of the Rybinsk Reservoir together with other fish species that form the feeding colonies of planktophagous fish. [19] The studies were carried out with the integrated monitoring of the Ivankovo and Rybinsk reservoirs. [20] The fate of microcystin-LR (MC-LR) in water samples of Rybinsk Reservoir taken before and during water bloom was assessed. [21] The model was constructed on the basis of the data published for the Rybinsk Reservoir and Mongolian lakes. [22] The aim of this study was to investigate biomarkers of oxidative stress: сatalase (CAT), glutathione (GR), glutathione S-transferase (GST), low-molecular antioxidant—reduced glutathione (GSH) and lipid peroxide oxidation marker—malondialdehyde (MDA) and to measure heavy metal (НМ) concentrations in Dreissena polymorpha soft tissues at three different sampling sites in the Rybinsk reservoir (one of the largest in Europe) in order to assess exposure to anthropogenic pollution. [23] —The effect of pH on the activity of peptidases and glycosidases functioning in the intestine and the supply of these enzymes in five fish species from the Rybinsk Reservoir with different feeding habits (roach Rutilus rutilus, bream Abramis brama, perch Perca fluviatilis, zander Zanderlucioperca, and pike Esox lucius) has been studied. [24] The structural parameters of phytoplankton in the estuarine region of a small tributary (Ild River) were studied in 2009–2011 and compared with the adjacent sections of the free-flowing section of the river and the pelagic zone of the Rybinsk Reservoir. [25] Most of the revealed taxa (61%) are common for Dreissena polymorpha (Pallas, 1771) biocenoses in the Rybinsk Reservoir; other species have invaded mesocosms during the experiment. [26] The characteristics of cardioactivity and the accumulation of metals in the tissues of bivalve mollusks from different water areas of the eastern Gulf of Finland and Rybinsk Reservoirs have been considered. [27] ) from areas of the Rybinsk reservoir subjected to different degrees of anthropogenic load have been studied. [28] On the basis of our own and published data, the contribution of autotrophic communities to the total primary production in the ecosystem of the Rybinsk Reservoir was estimated during the vegetation season in 2009. [29] The abundances of virioplankton and planktonic picocyanobacteria in deep and shallow water sites of Rybinsk Reservoir during the freezing period (water temperature 0. [30] In the mesoeutrophic Rybinsk Reservoir and eutrophic Ivan’kovo Reservoir, bacteriobenthos accounts for 90. [31] The seasonal and long-term dynamics of phytoplankton primary production has been studied in the Rybinsk Reservoir (Upper Volga) in 2005–2014. [32] The data on the finding of Eustrongylides excisus in the Rybinsk Reservoir (Yaroslavl oblast, Russia) are presented. [33] The dynamics and relationship between planktonic algae, bacteria, protozoa, invertebrates, and viruses were studied at different sites in shallow littoral zones of the Rybinsk Reservoir (Upper Volga) in April–June. [34] In July–August 2018, in four variants of microcosms, the conditions were modeled characteristic of the coastal zone of the Rybinsk Reservoir in the period of mass development of cyanobacteria. [35] This method allowed us to clarify the periodization of the process of naturalization of the Black Sea sprat (Clupeonella cultriventris) in the Rybinsk Reservoir and in detail describe the changes in the main dynamic characteristics of the population. [36] Cardioactivity indicators and accumulation of metals in the tissues of the mollusks from various waters of the eastern part of the Gulf of Finland and the Rybinsk Reservoir were used to characterize the ecosystems, and an original hyperosmotic test was used to analyze the functional state of the mollusks. [37] pantocsekii Wislouch & Kolbe in deep-water benthos of the Rybinsk reservoir, the Upper Volga Region. [38] The method was first used to analyze the structure of phytoplankton communities in the Ivankovo and Rybinsk reservoirs. [39] An analysis of the results of long-term observations has demonstrated changes in the species structure and a significant increase in the abundance of macrozoobenthos in the deepwater part of the Rybinsk Reservoir in extremely warm years at the beginning of 21st century. [40]考虑了 1947 年至 2020 年期间雷宾斯克水库水位的长期和季节性动态。 [1] 分析了 Rybinsk 水库中不同饲料类型的蟑螂 Rutilus rutilus (Linnaeus, 1758) 的咽齿(带有牙齿的咽颌)的质量及其在总体质量中的比例。 [2] 从雷宾斯克水库(俄罗斯)采集的两批天然底部沉积物中分别将幼虫维持 20 天,每批的多氯联苯含量不同(425. [3] 2015 年 5 月至 2019 年 10 月获得了雷宾斯克水库标准站叶绿素含量的新数据,这些数据继续进行了一系列长期观测。 [4] 我们研究的目的是研究流经雅罗斯拉夫尔地区的涅库兹和布雷托夫斯基区并流入雷宾斯克水库的切斯纳瓦河河口段的植被覆盖情况。 [5] 收集食物网的关键环节——浮游生物、微附生生物、碎屑和底栖无脊椎动物——在中宇宙暴露 20 天后,对碳 (δ 13 C) 和氮 (δ 15 N) 进行稳定同位素分析,以模拟海洋环境的条件。雷宾斯克水库的近岸生物群落没有蓝藻(变体 I)和高丰度的蓝藻(变体 II)。 [6] 所有被研究的河流都流入雷宾斯克水库,并具有不同的研究河口形态。 [7] 样本于 2015 年至 2018 年 8 月在上伏尔加河的三个大型水库(56°51'-58°22'N、35°55'-38°25'E)的 26 个站点采集:Ivankovo、Uglich 和 Rybinsk 水库。 [8] — 本文报道了在雷宾斯克水库(伏尔加河)捕获的不同大小的欧洲鲈鱼幼体的大型寄生虫负荷和攻击性的研究。 [9] , 1758 来自雷宾斯克水库,于 2016-2019 年收集。 [10] 根据2000-2005年雷宾斯克水库不同河段的浮游植物研究,分析了代表不同形态功能组的物种比例的变化,通过生理、形态和生态参数[29]。 [11] 0 μg/L),水库被归类为富营养化;雷宾斯克水库仅在凉爽的 2017 年(10. [12] 作者介绍了通过两种独立方法获得的雷宾斯克水库水域空间大地测量系统“GEO-IK-2”的卫星测高测量校准结果。 [13] 在波兰(Wigry 湖)、立陶宛(Elektrenai 水库和 Sirvinta 河)、俄罗斯、白俄罗斯(Lepelskoe 湖和 Lukomskoe 湖)以及俄罗斯的 Leuciscus idus、Scardinius erythrophthalmus(伏尔加河上的 Rybinsk 水库)中发现的斑马贻贝中的大子叶. [14] 大多数实验是在来自雷宾斯克水库的成年鲷(Abramis brama L)上进行的。 [15] 本研究分析了 2017 年极端高水位雷宾斯克水库的流入、径流和水位。 [16] 对雷宾斯克水库中的叶绿素a、氮、磷化合物进行了相关性分析。 [17] 介绍了 2009 年 5 月至 2019 年 10 月在六个标准站使用荧光法获得的雷宾斯克水库(俄罗斯上伏尔加河)浮游生物中叶绿素的季节性和长期动态数据。 [18] ) 栖息在雷宾斯克水库主要河段和河流河段的开阔远洋海域,与其他鱼类一起形成浮游鱼类的觅食群。 [19] 这些研究是通过对伊万科沃和雷宾斯克水库的综合监测进行的。 [20] 评估了在水华爆发前和水华期间采集的雷宾斯克水库水样中微囊藻毒素-LR (MC-LR) 的命运。 [21] nan [22] nan [23] nan [24] nan [25] nan [26] nan [27] nan [28] nan [29] nan [30] nan [31] nan [32] nan [33] nan [34] nan [35] nan [36] nan [37] nan [38] nan [39] nan [40]