6种陕北适生豆科植物生长对原油污染土壤的响应

为筛选优良的石油污染土壤修复植物,选取陕北适生的6种豆科乡土植物,对不同浓度原油污染土壤中植物的生长差异进行研究.采用混油法盆栽试验,分设0、5 000、10 000、20 000、40 000 mg·kg-1共5个不同的原油污染浓度,分析其对土壤理化性质的改变,对植物出芽时间、出芽率、株高、植物干重、叶绿素含量和枯萎率的影响.结果表明,原油污染显著改变土壤理化性质.5 000 mg·kg-1低浓度原油污染,对受试植物的发芽率和植物株高有促进作用,后随原油浓度加大植物生长受到明显抑制.原油污染浓度低时草本植物耐受力较强,其中紫花苜蓿(Medicago sativa)在出芽时间、出芽率、株高及枯萎率等方面综合表现较优.从40 000 mg·kg-1浓度时枯萎率及叶绿素含量分析,刺槐(Robinia pseudoacacia)表现较高的耐受力.相关分析表明,原油污染浓度与植物出芽时间、出芽率、株高、干重均呈显著负相关,但与叶绿素含量呈极显著正相关.     

冬季东海、南黄海中DMS和DMSP浓度分布及影响因素研究

于2011年12月~2012年1月现场测定了东海、南黄海表层海水中二甲基硫(DMS)及其前体物质二甲巯基丙酸内盐(DMSP分为溶解态DMSPd和颗粒态DMSPp)的含量,研究了它们的浓度分布规律及其影响因素,并对DMSPp的粒级分布和DMS的海-气通量进行了探讨.结果表明,表层海水中DMS、DMSPd和DMSPp的浓度分别在0.58~4.14、0.37~7.86和4.29~25.76 nmol·L-1之间,平均值分别为(2.20±0.82)、(2.12±1.66)和(11.98±6.23)nmol·L-1.DMS、DMSPp与叶绿素a(Chl-a)呈现明显的正相关关系,并且它们的周日变化趋势基本一致,说明浮游植物生物量是影响研究海域内DMS和DMSP生产分布的关键因素.另外,DMSPd浓度和总细菌丰度表现出一定的负相关,这可能是在细菌释放的DMSP裂解酶的作用下DMSPd会发生裂解生成DMS.研究发现,5~20μm的微型浮游植物是海区内Chl-a和DMSPp的主要贡献者.此外,冬季东海、南黄海表层海水DMS的海-气通量在0.61~25.52μmol·(m2·d)-1之间,平均值为(8.30±5.92)μmol·(m2·d)-1.     

黄河口不同恢复阶段湿地土壤N2O产生的不同过程及贡献

采用时空替代法,选择黄河口生态恢复前后未恢复区(R0)、2007年恢复区(R2007)和2002年恢复区(R2002)的芦苇湿地为研究对象,分析了生态恢复工程对湿地土壤N2O产生不同过程与贡献的影响.结果表明,尽管不同恢复阶段湿地土壤N2O总产生量差异明显,但总体均表现为N2O释放.恢复区湿地土壤的N2O产生量大于未恢复区.N2O的产生主要以硝化作用和硝化细菌反硝化作用为主,而反硝化作用对N2O的产生有较大削弱作用,这与不同恢复阶段湿地土壤理化性质密切相关.非生物作用对N2O产生量贡献较大,这与黄河口为高活性铁区,Fe的还原作用关系密切.尽管黄河口不同恢复阶段湿地土壤N2O的产生是生物作用与非生物作用共同作用的结果,但由于非生物作用对N2O产生的影响较大,应受到特别关注.温度和水分对不同恢复阶段湿地土壤N2O产生过程的影响不尽一致,这与土壤微生物活性对温度和水分的响应差异有关.黄河口不同恢复阶段湿地土壤的N2O总产生量介于(0.37±0.08)～(9.75±7.64)nmol·(kg·h)-1,略高于闽江口互花米草湿地的N2O总产生量,但明显低于富氧森林土壤、草原土壤和闽江口短叶茳芏湿地的N2O总产生量.研究发现,黄河口生态恢复工程的长期实施明显促进了N2O的产生,因而下一步生态恢复工程应统筹考虑景观恢复与温室气体削弱这两方面因素.     

铁岭市黄标车淘汰影响因素研究

通过对铁岭市近3年汽车和黄标车保有量变化及其氮氧化物排放量变化的研究,得出禁止转入是铁岭市黄标车淘汰的关键因素。     

秋夏季黄河三角洲湿地土壤汞和甲基汞的变化

汞在湿地中的行为对湿地水生生物健康具有重要影响.于2011年和2012年分别采集干(夏初)湿(秋季)季节黄河三角洲湿地土壤样品,分析不同季节汞与甲基汞的含量差异和垂直变化.秋季总汞平均含量为0.064 mg·kg-1;夏季为0.027 mg·kg-1,总汞含量平均减少57%,湿地由积水到干旱过程中导致汞的释放.秋季各点位0~10 cm深甲基汞平均含量为0.28μg·kg-1,夏季甲基汞平均含量为0.066μg·kg-1,各点位含量平均减少76%.在秋季受湿地淹水影响,利于甲基汞的形成,水分减少和湿地干旱导致土壤中的甲基汞减少.在垂直方向上,夏季与秋季相比总汞在0~10 cm深度都有减少,土壤中的汞发生释放,因此,湿地在秋季表现为汇,而在春夏季为大气汞的源.硫酸盐还原细菌的含量秋季远高于夏季,在夏季硫酸盐还原菌与甲基汞和甲基化率均显著相关,硫酸盐还原菌、淹水环境、有机物质都会影响甲基汞产生和分布.     

中国南中国海海岸湿地退化现状和保护对策

南中国海湿地包括广东省、香港特别行政区、澳门特别行政区、广西壮族自治区和海南省等五个行政区,总面积为15 393.75 km2。由于受人口增加和经济发展的巨大压力,中国南中国海湿地破坏严重,退化趋势明显。本文在对中国南中国海地区海岸湿地的现状、类型及湿地退化的主要原因进行分析的基础上,提出中国南中国海地区海岸湿地资源保护与管理的建议,以便切实保护中国南中国海沿海多样化的湿地类型,持续发挥其生态服务功能。     

Levels of polycyclic aromatic hydrocarbons in some agricultural, industrial and urban areas along Xiamen coastal waters, China

An intensive investigation was conducted to study the distribution of polycyclic aromatic hydrocarbons （PAHs）, to show firstly the level of pollution in the agricultural areas and analyses specifically the status of soil polluted by these persistent pollutants in some locations of Xiamen region. Soil samples collected from Jiulong agricultural catchment have been analysed for 16 PAH compounds, using gas chromatography flame ionization detection in order to determine the level of selected PAH components and to identify the factors that may control their distribution and persistence in the area. The main PAHs found in soil samples were the low molecular weight. The total PAHs detected in soil samples ranged from 0.50 to 0.95 μg/g soil. The highest values of PAHs were significantly detected in the orange tree leaves, which range from 236.1 to 249.3 μg/g soil showing recent atmospheric inputs of these volatile pollutants. The distribution of PAHs in vegetable were monitored and indicating that the concentration were high and ranged from 8.24 to 58.87 μg/g. Other sediment samples were also collected and analysed from urban sewage （5.26 μg/g dw）, aquacultural （0.52 μg/g dw） and industrial areas （from 0.62 to 2.09 μg/g dw）, during this investigation. The contamination of Jiulong river estuary and Xiamen Western Sea by PAHs has been then widely justified by wastcwatcr discharges and soil runoffs from these areas. The results, therefore, provide important information on the current contamination status caused by the atmospheric transport and point to the need for urgent actions to stop the release of these hydrocarbons to the environment. The necessity of implementing systematic monitoring of PAHs is also emphasized.     

Eco-Environmental Degradation in the Source Region of the Yellow River, Northeast Qinghai-Xizang Plateau

The Yellow River is the second longest river in China and the cradle of the Chinese civilization. The source region of the Yellow River is the most important water holding area for the Yellow River, about 49.2% of the whole runoff comes from this region. However, for the special location, it is a region with most fragile eco-environment in China as well. Eco-environmental degradation in the source region of the Yellow River has been a very serious ecological and socially economic problem. According to census data, historical documents and climatic information, during the last half century, especially the last 30 years, great changes have taken place in the eco-environment of this region. Such changes are mainly manifested in the temporal-spatial changes of water environment, deglaciation, permafrost reduction, vegetation degeneracy and desertification extent, which led to land capacity decreasing and river disconnecting. At present, desertification of the region is showing an accelerating tendency. This paper analyzes the present status of eco-environment degradation in this region supported by GIS and RS, as well as field investigation and indoor analysis, based on knowledge, multi-source data is gathered and the classification is worked out, deals with their natural and anthropogenic causes, and points out that in the last half century the desertification and environmental degradation of this region are mainly attributed to human activities under the background of regional climate changes. To halt further degradation of the environment of this region, great efforts should be made to use land resources rationally, develop advantages animal agriculture and protect the natural grassland.     

Trace Metal Levels in Mussels (Mytilus Galloprovincialis L. 1758) from Turkish Aegean Sea Coast

Bio-monitoring of some heavy metal levels (Cd, Pb, Zn, Cu) in whole edible soft parts of Mytilus galloprovincialis (L. 1758) was conducted in Turkish Aegean Sea coast during the period of September 2002–August 2003 seasonally. Moreover, some physico-chemical environmental parameters, also have been analysed in the same region. The values of some physico-chemical environmental parameters in coastal waters of Turkish Aegean Sea were changed between; 9.0–27.0 ^∘C for temperature, 31.93–40.45 psu for salinity, 7.35–8.48 for pH and 4.05–9.50 mg/l for dissolved oxygen. The levels of trace elements in whole edible soft parts including interstitial fluids of Mediterranean mussels M. galloprovincialis (L. 1758), sampled from 6 different regions of Turkish Aegean Sea coast have ranged between; 0.04–0.52 μg Cd/g wet weight, 0.49–1.72 μg Pb/g w.w., 0.95–1.85 Cu/g w.w., 16.11–37.15 μg Zn/g w.w. The highest values for all trace metals (Cd, Pb, Zn, Cu) were measured in inner part of Izmir Bay (station 3) and lowest in Sigacik and Gulluk Bay (station 5, 6). Generally heavy metal levels are lower than the results in soft mussel tissues reported from Mediterranean regions.     

Monitoring a changing Arctic: Recent advancements in the study of sea ice microbial communities

Sea ice continues to decline across many regions of the Arctic, with remaining ice becoming increasingly younger and more dynamic. These changes alter the habitats of microbial life that live within the sea ice, which support healthy functioning of the marine ecosystem and provision of resources for human-consumption, in addition to influencing biogeochemical cycles (e.g. air–sea CO₂ exchange). With the susceptibility of sea ice ecosystems to climate change, there is a pressing need to fill knowledge gaps surrounding sea ice habitats and their microbial communities. Of fundamental importance to this goal is the development of new methodologies that permit effective study of them. Based on outcomes from the DiatomARCTIC project, this paper integrates existing knowledge with case studies to provide insight on how to best document sea ice microbial communities, which contributes to the sustainable use and protection of Arctic marine and coastal ecosystems in a time of environmental change.Supplementary InformationThe online version contains supplementary material available at 10.1007/s13280-021-01658-z.