胶州湾东北部养殖海区环境质量状况及分析

基于2006年2月、5月、8月、11月胶州湾东北部养殖海区现场调查结果,采用单因子指数、富营养化指数、有机污染指数对环境状况进行了分析评价。结果表明:该海域主要受到无机N、P污染;COD在夏、秋季符合一类,但在冬、春季只达到国家二类海水水质标准;DO全部符合国家一类海水水质标准。通过站位间的比较发现,东北部沧口水域环境质量最差,全年处于富营养化状态,有机污染介于轻度到严重污染之间。红岛附近水质较好,不存在有机污染,只有春、秋季达到富营养化水平。研究结果显示该海域主要受陆源污染,且与现有污水处理不能有效去除无机N、P营养盐有关。     

2013年夏季曹妃甸邻近海域浮游植物群落的空间格局及其影响因素

为阐明曹妃甸邻近海域浮游植物群落的水平和垂直分布特征,于2013年8月在该海域开展调查航次,应用Uterm9hl方法研究了浮游植物的物种组成、细胞密度和优势种等特征,采用冗余分析(RDA)和聚类分析探讨了浮游植物群落的空间分布特征及其与环境因子的关系。结果表明,本次调查共鉴定得到浮游植物3门34属66种,主要由硅藻和甲藻组成,浮游植物密度范围为(0.85～39.07)×10~4cells/L,主要优势种为长菱形藻(Nitzschia longissima)、中肋骨条藻(Skeletonema costatum)和浮动弯角藻(Eucampia zodiacus)等。浮游植物密度的空间分布与温度、盐度和营养盐等环境因子密切相关。水平方向上,近岸海域的细胞密度通常高于远岸海域,主要与陆源营养盐输入有关。垂直方向上,浮游植物群落的变化主要出现在水深超过20 m的远岸海域,细胞密度随深度增加而降低,大部分硅藻和甲藻主要分布在表层水体,而具槽帕拉藻(Paralia sulcata)等底栖种类主要分布在中层和底层水体,这些主要与海水的垂直混合受到抑制有关。     

海南省三亚市三亚湾珊瑚礁区环境特征

2011年春季和冬季对三亚湾水体和沉积物的现场调查表明,三亚湾水体中营养盐的含量存在显著的季节变化,春季水体中的氮、磷等营养元素显著低于冬季的;而三亚河输入的陆源营养元素对三亚湾的影响显著。总氮总磷的分析结果表明,水体中有机营养元素的含量较高,由于浮游植物也可以利用有机氮和磷来进行初级生产,因此,水体中有机质的污染应引起重视。历年来海水中无机氮、磷的监测结果表明,三亚湾水体中氮的输入有逐年增加的趋势,而磷的污染有逐渐降低的趋势。水体中N/P比值也由2004年的6∶1,增加到2011年的60~123∶1;说明整个生态系统已由早期的氮限制转变为磷限制。沉积物重金属元素的分析结果显示,三亚湾除了三亚河口附近的Cd元素超标外,大部分海区的沉积物依然属于国家一类沉积物,处于清洁环境下。而水体水温的长期监测结果表明,三亚湾水体水温的变化波动有增大的趋势,且水体的酸化现象也和全球的变化一致,说明三亚湾水体也受到全球气候变化的影响,但总体上三亚湾珊瑚礁周围环境状况较为稳定,可满足珊瑚礁的生长要求。     

沙子口湾海水环境容量初步研究

为了保护沙子口湾的海域生态环境 ,防止湾内水体的污染 ,必须对湾内水体的环境容量进行估价 ,也就是通过湾内水体纳污能力的研究 ,制定相应的对策和总量控制方案 ,有效地控制湾内的水质状况。目前 ,对“环境容量”的定义不一 ,笔者认为“环境容量”是指某一环境单元所允许承纳污染物质的最大负荷量。它是一个变量并包括两个组成部分 ,即基本环境容量 (或称差值容量 )和变动环境容量 (或称同化容量 )。前者可以通过拟定的环境标准减去环境本底值求得 ,后者是指该环境单元的自净能力。所谓海湾水体的环境容量是指泄入湾内水体中污染物质的总量…     

渤海春季营养盐限制的现场实验

1999年4－5月，在现场条件下对天然水体中浮游植物以外加营养盐受控培养的方式，研究和探讨春季渤海中部、莱州湾和渤海海峡3个海区的浮游植物生长的营养盐限制问题。结果表明，在莱州湾附近浮游植物生长受到显著的磷限制；尽管水体中硅酸盐浓度较历史水平大大降低，并且实验进行时硅藻为优势种，但是硅酸盐尚不成为限制因子；渤海中部不存在营养盐的限制问题，营养盐浓度和结构相对适宜；渤海海峡也不存在营养盐的限制问题，但是溶解无机氮的相对含量略低。     

防城湾水质特征及营养状况趋势研究

根据1983—1984年度、1990年度及1996——1997年度3个不同时期的调查研究资料，分析研究了防城湾的水质特征及其营养状况。结果表明：该湾水体中的盐度、pH呈明显下降趋势，而有机污染物含量则呈上升趋势，其余因子无明显规律性变化；但相关分析显示，陆源输入对各化学因子具有主导控制作用，生物同化作用次之。N、P、Si营养盐中，N为1983—1984年度初级生产力的限制因子：1990年度演化为P和Si;1996—1997年度N、P、Si均呈充足状态，尤以Si最为显著。通过污染指数A及营养状态指数E的统计分析，该湾水质具有向污染型及富营养型演化的明显趋势。     

沙海蜇(Nemopilema nomurai)代谢及分解过程对水环境理化因子及浮游植物影响的研究

从上行控制角度,通过野外采样和围隔培养实验,研究了水母的代谢及分解过程对水体环境中pH、溶解氧、营养盐组成的影响,以及该过程中浮游植物的变化。实验结果表明,沙海蜇在代谢过程中短时间内会大量消耗水体中的溶解氧(dissolved oxygen,DO),使水体出现低氧和轻度酸化。代谢过程释放出大量营养盐,使水体中的溶解无机氮(dissolved inorganic nitrogen,DIN)浓度在24h内增加为原来的12倍,溶解无机磷(dissolved inorganic phosphorus,DIP)浓度增加了40多倍,进而引起水体中叶绿素a(chlorophyll a,chl a)浓度的增加。沙海蜇的分解过程使水体表现出明显的低氧(缺氧)和酸化现象。沙海蜇生物量越大,分解时间越长,对水体的改变程度越明显,此外,还释放出大量的营养盐并改变原有的营养盐结构,可以刺激甲藻和绿藻的生长,甚至可能引发藻华。     

厦门湾营养盐长期动态变化与陆源污染关系分析

近年来快速城镇化和人类活动导致沿海地区营养盐含量显著增加,导致海湾富营养化现象日趋严重。了解水体营养盐含量分布特征与陆源污染之间的关系,是对海湾进行有效环境管理的前提。本研究以2010—2019年福建省厦门湾近岸海域水质监测数据为基础,分析长期性、季节性水质空间分布特征,并利用富营养化指数法对海湾富营养化状态进行评价,为氮、磷污染物治理提供措施建议。结果表明：厦门湾自2013年以来无机氮、无机磷含量波动降低,但同安湾无机磷含量近年来有明显增加。春季和秋季无机氮、无机磷含量明显高于夏季,不同季节氮、磷含量均呈现由湾内向湾外递减的分布趋势,反映出典型的陆源输入特征。硝酸盐氮是厦门湾无机氮的最主要成分,其与无机磷的比值普遍高于Redfield比值。无机氮、无机磷是导致九龙江口、西海域、同安湾富营养化指数较高的主要因子,受径流调控明显,无机磷在秋季还受到沿岸排污口的显著影响。厦门湾亟需加强对所有入海河流氮、磷污染的总量控制,建议强化沿岸排污口的管控。     

沙海蜇(Nemopilema nomurai)代谢及分解过程对水环境理化因子及浮游植物影响的研究

从上行控制角度,通过野外采样和围隔培养实验,研究了水母的代谢及分解过程对水体环境中pH、溶解氧、营养盐组成的影响,以及该过程中浮游植物的变化。实验结果表明,沙海蜇在代谢过程中短时间内会大量消耗水体中的溶解氧（dissolved oxygen,DO）,使水体出现低氧和轻度酸化。代谢过程释放出大量营养盐,使水体中的溶解无机氮（dissolved inorganic nitrogen,DIN）浓度在24h内增加为原来的12倍,溶解无机磷（dissolved inorganic phosphorus,DIP）浓度增加了40多倍,进而引起水体中叶绿素a（chlorophyll a,chl a）浓度的增加。沙海蜇的分解过程使水体表现出明显的低氧（缺氧）和酸化现象。沙海蜇生物量越大,分解时间越长,对水体的改变程度越明显,此外,还释放出大量的营养盐并改变原有的营养盐结构,可以刺激甲藻和绿藻的生长,甚至可能引发藻华。     

早灌赤潮与水体中营养盐的关系初探

作者在国家海洋局第三海洋研究所的陆基水池中，应用围隔实验技术，排除了水动力、盐度等环境因子的变动性的干扰，人工诱发甲藻赤潮。在这个围隔实验的两个围隔体中，分别发生了一种裸甲藻（Gymnodinium sp.)海洋原甲藻（Prorocentum micans）的赤潮。在赤潮发生和发展过程中所监测到的营养盐数据表明：有些甲藻增殖不一定需要水体中高营养盐；营养盐供给的多寡会导致甲藻赤潮优势种的差异和赤潮规模。     

Seasonal variations in nutrients and chlorophyll-a concentrations in the Northern east China sea

Nutrients, chlorophyll-a, particulate organic carbon (POC), and environmental conditions were extensively investigated in the northern East China Sea (ECS) near Cheju Island during three seasonal cruises from 2003 to 2005. In spring and autumn, relatively high concentrations of nitrate (2.6~12.4 μmol kg^-1) and phosphate (0.17~0.61 μmol kg^-1) were observed in the surface waters in the western part of the study area because of the large supply of nutrients from deep waters by vertical mixing. The surface concentrations of nitrate and phosphate in summer were much lower than those in spring and autumn, which is ascribed to a reduced nutrient supply from the deep waters in summer because of surface layer stratification. While previous studies indicate that upwellings of the Kuroshio Current and the Changjiang (Yangtze River) are main sources of nutrients in the ECS, these two inputs seem not to have contributed significantly to the build-up of nutrients in the northern ECS during the time of this study. The lower nitrate:phosphate (N:P) ratio in the surface waters and the positive correlation between the surface N:P ratio and nitrate concentration indicate that nitrate acts as a main nutrient limiting phytoplankton growth in the northern ECS, contrary to previous reports of phosphate-limited phytoplankton growth in the ECS. This difference arises because most surface water nutrients are supplied by vertical mixing from deep waters with low N:P ratios and are not directly influenced by the Changjiang, which has a high N:P ratio. Surface chlorophyll-a levels showed large seasonal variation, with high concentrations (0.38~4.14 mg m^-3) in spring and autumn and low concentrations (0.22~1.05 mg m^-3) in summer. The surface distribution of chlorophyll-a coincided fairly well with that of nitrate in the northern ECS, implying that nitrate is an important nutrient controlling phytoplankton biomass. The POC:chlorophyll-a ratio was 4~6 times higher in summer than in spring and autumn, presumably because of the high summer phytoplankton death rate caused by nutrient depletion in the surface waters.     

Nitrogen and phosphorus species in the coastal and shelf waters of Southeastern North Carolina, Mid-Atlantic U.S. coast

The diversity of small-scale wetlands, high salinity tidal creeks, salt marshes, estuaries, and a wide and shallow shelf with the Gulf Stream close to the break makes the coastal zone of south-eastern North Carolina (U.S.) a natural laboratory for the study of the cycling of nitrogen (N) and phosphorus (P) in coastal and shelf waters. We assessed the summer concentrations, forms, and ratios for each N (total dissolved N, nitrate + nitrite, ammonium and dissolved organic N) and P (total dissolved P, o-phosphate and dissolved organic P) pool as these nutrients travel from tidal creeks, salt marshes and two large estuaries to Long and Onslow Bays. Additionally, we measured ancillary physical (temperature, salinity and turbidity) and chemical (dissolved oxygen, chlorophyll a and pH) water properties. Highest concentrations of all individual N and P compounds were found in the upper parts of each tributary and were attributed to loads from agricultural and urban sources to the coastal watersheds, continuing downstream to receiving estuaries. In all areas, dissolved organic N and P species were predominant constituents of the total dissolved N and P pools (64–97% and 56–93%, respectively). The lower parts of estuaries and surface shelf waters were characterized by oceanic surface values, indicating removal of N and P downstream in all tributaries. The different watershed and hydrological characteristics also determined the different speciation of N and P pools in each estuary. Despite a high level of anthropogenic pressure on the uppermost coastal waters, there is self-regulation in this coastal ecosystem with respect to human perturbations; i.e. significant amounts of the N and P load are retained within estuarine and nearshore waters without reaching the shelf.     

Factors affecting spatial and temporal variability in material exchange between the Southern Everglades wetlands and Florida Bay (USA)

Physical and biological processes controlling spatial and temporal variations in material concentration and exchange between the Southern Everglades wetlands and Florida Bay were studied for 2.5 years in three of the five major creek systems draining the watershed. Daily total nitrogen (TN), and total phosphorus (TP) fluxes were measured for 2 years in Taylor River, and ten 10-day intensive studies were conducted in this creek to estimate the seasonal flux of dissolved inorganic nitrogen (N), phosphorus (P), total organic carbon (TOC), and suspended matter. Four 10-day studies were conducted simultaneously in Taylor, McCormick, and Trout Creeks to study the spatial variation in concentration and flux. The annual fluxes of TOC, TN, and TP from the Southern Everglades were estimated from regression equations. The Southern Everglades watershed, a 460-km² area that includes Taylor Slough and the area south of the C-111 canal, exported 7.1 g C m⁻², 0.46 g N m⁻², and 0.007 g P m⁻², annually. Everglades P flux is three to four orders of magnitude lower than published flux estimates from wetlands influenced by terrigenous sedimentary inputs. These low P flux values reflect both the inherently low P content of Everglades surface water and the efficiency of Everglades carbonate sediments and biota in conserving and recycling this limiting nutrient. The seasonal variation of freshwater input to the watershed was responsible for major temporal variations in N, P, and C export to Florida Bay; approximately 99% of the export occurred during the rainy season. Wind-driven forcing was most important during the later stages of the dry season when low freshwater head coincided with southerly winds, resulting in a net import of water and materials into the wetlands. We also observed an east to west decrease in TN:TP ratio from 212:1 to 127:1. Major spatial gradients in N:P ratios and nutrient concentration and flux among the creek were consistent with the westward decrease in surface water runoff from the P-limited Everglades and increased advection of relatively P-rich Gulf of Mexico (GOM) waters into Florida Bay. Comparison of measured nutrient flux from Everglades surface water inputs from this study with published estimates of other sources of nutrients to Florida Bay (i.e. atmospheric deposition, anthropogenic inputs from the Florida Keys, advection from the GOM) show that Everglades runoff represents only 2% of N inputs and 0.5% of P input to Florida Bay.     

丰、枯水期长江口邻近海域浮游植物群落结构特征及其环境影响初探

通过2013年3月和8月在长江口及其邻近海域进行的多学科综合调查,研究了枯水期和丰水期浮游植物的群落结构和空间分布特征,并探讨了影响其分布的环境因子效应。枯水期共发现浮游植物3门41属80种（不包括变种和变型）,以硅藻为主,主要优势种为具槽帕拉藻（Paralia sulcata）;浮游植物细胞丰度介于0.15×103~16.35×103 cells/L,平均值为（3.24±3.14）×103 cells/L;浮游植物细胞丰度在长江口外东北部海域形成高值,垂直变化较小,硅藻刻画了浮游植物的空间分布。丰水期共发现浮游植物4门67属135种（不包括变种和变型）,甲藻物种数量和细胞丰度均升高,主要优势种为东海原甲藻（Prorocentrum donghaiense）和骨条藻（Skeletonema sp.）;浮游植物细胞丰度介于0.2×103~1 925.45×103 cells/L,平均值为（41.67±186.00）×103 cells/L;浮游植物细胞丰度在长江口外形成南北两个高值区,随水深增加,细胞丰度逐渐降低。浮游植物的空间分布受长江口冲淡水影响,与盐度和浊度有显著的相关性;N/P比影响浮游植物群落结构,随着N/P比升高,甲藻的相对丰度升高,硅藻的相对丰度逐渐降低。浮游植物在层化水体的上层大量繁殖是底层低氧形成的必要条件,硅藻具有较高的沉降速率,因而以硅藻为主的群落更利于低氧的形成。     

春季长江口及毗邻海域浮游动物空间分布及与环境因子的关系

于2009年4月15～23日在长江口及其邻近海域进行了32个站位的浮游动物生态调查,分析了浮游动物的种类组成、优势种、丰度和生物量的空间分布,并利用PRIMER生物统计学软件中的PCA、BIOENV和RELATE程序分析了浮游动物与环境因子的关系.共发现浮游动物成体72种,浮游幼虫9种,合计种类数为81.中华哲水蚤(C...     

珠江口夏季水体中的氮和磷

根据1999年7月17～28日于珠江口现场调查和实验的资料,研究夏季水体中氮、磷的分布、形态变化和初级生产力的限制因素.结果表明该海域氮含量高,N/P属于世界上高值区之一.从河口向外海运输过程中,氮和磷的形态和浓度均有剧烈的变化.虽然氮在中途中有新源的补充;但由于外海水的入侵稀释、生物吸收和形态变化的迁移作用,NO₃-和可溶无机氮的浓度总的变化趋势仍是随盐度增大而大幅度地降低,以至珠江口外出现N/P低于16.由于夏季水体层化稳定,在表、底层其生物地球化学变化方向相反,PO₄3的浓度变化互成镜像关系并可按盐度分为3段不同特征的反应区.初级生产力的限制因素在大部分区域是磷,但从口门至最大浑浊带和口外区则分别是浊度(或光照)及可溶无机氮.现场培养实验再现了真光层和底层氮和磷的生物地球化学过程差异并表明磷的循环和再生比氮迅速;在可溶无机氮浓度大且高N/P的海域,磷的再生可成为水华的引发因素,而氮被耗尽却是水华消亡的原因.总体上夏季该区水体氮的迁出率比磷高.于水体层化稳定的区域,氮和磷的生物地球化学作用在真光层以浮游生物吸收占优势、在下层以有机物的降解和可溶无机态的再生为主,当层化消失、上下水体充分混合则可完成循环.     

Relationship between environment and the occurrence of the deep-water rose shrimp Aristeus antennatus (Risso, 1816) in the Blanes submarine canyon (NW Mediterranean)

We performed a multidisciplinary study characterizing the relationships between hydrodynamic conditions (currents and water masses) and the presence and abundance of the deep-water rose shrimp Aristeus antennatus in a submarine canyon (Blanes canyon in the NW Mediterranean Sea). This species is heavily commercially exploited and is the main target species of a bottom trawl fishery. Seasonal fluctuations in landings are attributed to spatio-temporal movements by this species associated with submarine canyons in the study area. Despite the economic importance of this species and the decreases in catches in the area in recent years, few studies have provided significant insight into the environmental conditions driving shrimp distribution. We therefore measured daily A. antennatus catches over the course of an entire year and analyzed this time series in terms of daily average temperature, salinity, mean kinetic energy (MKE), and eddy kinetic energy (EKE) values using generalized additive models and decision trees. A. antennatus was captured between 600 and 900 m in the Blanes canyon, depths that include Levantine Intermediate Water (LIW) and the underlying Western Mediterranean Deep Water (WMDW). The greatest catches were associated with relatively salty waters (38.5–38.6), low MKE values (6 and 9 cm² s⁻²) and moderate EKE values (10 and 20 cm² s⁻²). Deep-water rose shrimp occurrence appears to be driven in a non-linear manner by environmental conditions including local temperature. A. antennatus appears to prefer relatively salty (LIW) waters and low currents (MKE) with moderate variability (EKE).     

Cycles of chemical substances in the atmosphere,the Sea and the sea-floor

Since 1960 when I was a senior student, I have studied natural phenomena observed in the hydrosphere and atmosphere by means of chemical elements. Each of the phenomena is, in general, very complicated and so I have attempted to depict the whole picture of material circulation in the marine environment by studying its various aspects at the same time. My chief strategy has been to use natural radio-nuclides as clocks of various phenomena, and to use sediment traps for the determination of vertical fluxes in the ocean. The many results I have obtained can be summarized as follows. 1. I have found that several sporadic events control the material exchange through the atmosphere. These include the strong winter monsoon and typhoons that transport sea-salt particles to the Japanese Islands, theKosa episodes that transport soil dust to the ocean, and storms that result in exchange of sparingly soluble gases such as oxygen and carbon dioxide at the air-sea interface. I have also proved quantitatively that the source of aluminosilicate material in pelagic sediments is air-borne dust. 2. I have proposed a model,Settling model, for the removal of chemical substances from the ocean and found various lines of evidence supporting the model. This model predicts the reversibility in the existing state of insoluble chemical elements in seawater among large settling particles, small suspended particles and colloidal particles that pass through a membrane filter and explains well their behavior in the ocean. I have first precisely measured calcium and iodine in the ocean and have explained their distributions on the basis of the solution and redox equilibria. 3. Using chemical tracers, I have estimated the vertical eddy diffusion coefficients to be 1.2 cm²sec⁻¹ for the Pacific deep water, 0.5 cm²sec⁻¹ for the deep Bering Sea water and 3–80 cm²sec⁻¹ for the Pacific surface water, and have studied the structure of water masses in the western North Pacific and the Sea of Japan. I have also invented and applied a method for the calculation of the age of deep waters using radiocarbon. 4. I have calculated the rates of decomposition of organic matter and the regeneration rates of chemical components in the deep and bottom waters as well as coastal waters by modelling water circulation and mixing. Particulate fluxes and regeneration rates are larger in the deep waters beneath the more biologically productive surface waters. I have stressed the role of silicate in the marine ecosystem, especially in the succession of phytoplankton species. 5. I have quantitatively studied the migration of chemical elements during the early diagenesis of bottom sediments especially manganese using chemical and radiochemical techniques. Manganese is being actively recycled not only in coastal seas but also in pelagic sediments except in the highly oligotrophic subtropical ocean. This recycling can explain the formation of manganese nodules and enables us to balance the manganese budget in the ocean.     

秦山核电站邻近海域网采浮游植物群落分布及其影响因素

秦山核电站位于杭州湾北岸湾顶,其邻近海域受到钱塘江淡水径流和江浙沿岸流的共同影响,水体环境复杂。本研究根据2012年5月(春季)、10月(秋季)秦山核电站邻近海域15个站位网采浮游植物群落调查及理化因子测定,研究了该海域浮游植物群落结构、分布及其影响因子。同时比对历史数据,分析该海域浮游植物群落对环境变化的响应。调查共鉴定检出浮游植物5门60属139种(春季5门36属70种、秋季5门51属115种),其中硅藻42属110种(占85.3%),甲藻8属12种(占9.3%),绿藻、蓝藻和裸藻偶有检出。春季浮游植物平均丰度(1 802.62×104个/m~3)高于秋季(877.15×104个/m~3),其中琼氏圆筛藻Coscinodiscus jonesianus和中肋骨条藻Skeletoema costatum为两季优势种。聚类分析和典范对应分析表明,两季浮游植物群落差异显著,氮磷比、溶解无机氮、溶解无机磷和盐度是影响调查海域浮游植物的主要环境因子。比对历史资料得到,30年来秦山核电站邻近海域浮游植物赤潮藻种的增加和群落结构及丰度的改变受到营养盐含量及结构变化、水温升高等因素共同作用。     

环雷州半岛海域表层沉积物与鲬鱼汞污染研究

对2018年1月在广东环雷州半岛近海海域采集的海底表层沉积物、鲬鱼(Platycephalus indicus)进行汞含量的测定,分析比较了鲬鱼不同部位汞含量的差异,并采用单因子污染指数法对沉积物和鲬鱼的汞污染状况进行了风险评价。结果表明,环雷州半岛海域表层沉积物中汞含量范围为0.005×10^-6～0.359×10^-6,平均值为0.081×10^-6,雷州半岛东部海域表层沉积物汞含量高于南部和西部海域。鲬鱼的鳃中汞含量范围为0.032×10^-6～0.034×10^-6,平均值为0.033×10^-6;肌肉中的汞含量范围为0.065×10^-6～0.080×10^-6,平均值为0.073×10^-6;肝脏中的汞含量范围为0.228×10^-6～0.270×10^-6,平均值为0.249×10^-6。鲬鱼样品的汞含量都呈现出肝脏＞肌肉＞鳃。单因子污染指数评价结果显示,雷州半岛海域鲬鱼受到汞的轻微污染,雷州半岛东部海域表层沉积物存在汞污染生态风险,而其南部、西部海域尚未受到汞污染的威胁。