湖泊表层水体“甲烷悖论”现象研究进展

传统观点认为,甲烷(CH_4)产生于严格的厌氧环境,在有氧环境中容易被氧化,但许多湖泊表层有氧水体出现了CH_4过饱和现象,这种现象被称为"甲烷悖论"现象。为了解释湖泊"甲烷悖论"现象,本文根据湖泊表层CH_4的来源,归纳出"外来假说"和"自产假说"。"外来假说"假说认为,岸边浅水区底泥或消落区土壤产生CH_4向湖心表层水体横向扩散传输(F_L),这种假说适应于岸边富含有机质的小型浅水湖泊。"自产假说"认为,湖心表层水体中产甲烷古生菌原位产生CH_4(P),这种假说适应于山区大型深水湖泊。此外,湖泊表层有氧水体中CH_4的来源还有湖泊周围河流的输入(F_R)、沉淀物或次表层水体的CH_4垂直向上湍流扩散(F_Z)、气泡CH_4溶解在表层水体中(F_D)等,而湖泊表层有氧水体中CH_4的损耗有"水-气"界面上气体排放(E)、CH_4氧化(O)等。在厘清湖泊表层水体中CH_4收支的基础上,建立CH_4质量收支平衡模型,有助于客观认识湖泊表层水体中CH_4的来源。实际上,湖泊表层水体中过饱和甲烷的来源与湖泊的环境特性有关,但数据分析方法、取样时段、湖泊环境条件等差异,容易造成"外来假说"和"自产假说"之争。     

CO2浓度增加对长白山森林土壤甲烷氧化影响

大气CO2浓度升高可能对森林土壤的甲烷(CH4)氧化速率产生影响.本文采用开顶箱技术,对连续6年高浓度CO2(500 μmol·mol-1)处理的长白山森林典型树种蒙古栎树下土壤CH4氧化速率进行研究,并利用CH4氧化菌的16S rRNA特异性引物以及CH4单加氧酶功能基因引物分析了土壤中CH4氧化菌的群落结构与数量.结果表明:CO2浓度增高后,生长季土壤甲烷氧化量与对照和裸地相比分别降低了4％和22％;基于16S rRNA特异性引物的DGGE分析表明,CO2浓度增高导致两类甲烷氧化菌的多样性指数降低;CO2浓度增高对土壤中Ⅰ类甲烷氧化菌数量无显著影响,而使土壤中Ⅱ类甲烷氧化菌数量显著减少,功能基因pmoA拷贝数与对照和裸地相比分别降低了15％和46％.CO2浓度增高导致森林土壤甲烷氧化菌数量与活性降低,土壤含水量的增加可能是导致这一现象的主要原因.     

CO2浓度增加对长白山森林土壤甲烷氧化影响

大气CO2浓度升高可能对森林土壤的甲烷(CH4)氧化速率产生影响.本文采用开顶箱技术,对连续6年高浓度CO2（500 μmol·mol-1）处理的长白山森林典型树种蒙古栎树下土壤CH4氧化速率进行研究,并利用CH4氧化菌的16S rRNA特异性引物以及CH4单加氧酶功能基因引物分析了土壤中CH4氧化菌的群落结构与数量.结果表明： CO2浓度增高后,生长季土壤甲烷氧化量与对照和裸地相比分别降低了4%和22%;基于16S rRNA特异性引物的DGGE分析表明,CO2浓度增高导致两类甲烷氧化菌的多样性指数降低;CO2浓度增高对土壤中Ⅰ类甲烷氧化菌数量无显著影响,而使土壤中Ⅱ类甲烷氧化菌数量显著减少,功能基因pmoA拷贝数与对照和裸地相比分别降低了15%和46%.CO2浓度增高导致森林土壤甲烷氧化菌数量与活性降低,土壤含水量的增加可能是导致这一现象的主要原因.     

鄱阳湖秋季水-气界面CH4排放通量的区域差异及影响因素

有限的观测点以及空间的异质性已经成为准确估算湖泊水-气界面CH4通量的挑战。鄱阳湖是我国最大的淡水湖,为了解秋季湖区水-气界面的CH4排放通量,2010年10月利用密闭静态箱-气象色谱法对星子、都昌、南矶山和吴城4个湖区水-气界面CH4排放通量及气象、底泥、水体等因素进行了测定。研究表明,都昌湖区CH4排放通量平均值为0.26mg·m-2·h-1,显著高于星子(0.15mg·m-2·h-1)、吴城(0.13mg·m-2·h-1)和南矶山(0.10mg·m-2·h-1)湖区。鄱阳湖水-气界面秋季CH4排放通量平均为0.17mg·m-2·h-1,变异系数为58.6%。相关分析表明,风速显著影响CH4排放通量(P<0.01)。在排除风速>5m·s-1的数据后,底泥有机碳以及水体铵态氮含量与CH4排放通量显著相关,而水体DOC含量与CH4排放通量呈显著负相关(P<0.05)。对鄱阳湖CH4排放量的精确估算,依赖于较广区域和较长时间的观测。     

稻田甲烷排放模型研究——模型的验证

模型的有效性检验是模型应用于估计区域尺度稻田甲烷排放量的基本前提 ,尤其是针对多种不同的土壤、气候以及农业管理方式等可能影响稻田甲烷排放的环境条件下的模型检验。利用覆盖全国主要水稻产区的 94个甲烷排放观测案例对稻田甲烷排放模型 (CH4 MOD)进行了验证。这些观测区域分布范围北至北京 (4 0°30′N,116°2 5′E) ,南至广州 (2 3°0 8′N,113°2 0′E) ,东起杭州 (30°19′N,12 0°12′E) ,西到四川的土主 (2 9°4 0′N,10 3°5 0′E)。既有双季稻 ,也有单季稻 ,稻田灌溉及施肥方式也多种多样 ,对我国水稻生产具有较广泛的代表性。观测获得的稻田甲烷排放季节总量从 3.1kg C/hm2到 76 1.7kg C/hm2 ,平均值为199.4 (± 187.3) kg C/hm2 ;相应的模拟值分别为 13.9、82 4 .3和 2 2 4 .6 (± 187.0 ) kg C/hm2。模拟值与实测值的线性相关系数(r2 )为 0 .84 (n=94 ,p<0 .0 0 1)。CH4 MOD模型能够通过较少的输入参数有效地模拟我国主要农作方式下的稻田甲烷排放     

温度对亚热带地区常见树种叶片甲烷排放的影响

以亚热带常见树种米槠、木荷、浙江桂、罗浮栲、杉木和柑橘为对象,利用控制试验研究了温度对树木叶片甲烷(CH4)排放的影响.结果表明:当温度在10℃时,供试的6种树木中,仅木荷、柑橘和罗浮栲的叶片排放CH4;温度高于20℃时,所有树木叶片均可排放CH4.温度高于30℃时,叶片排放CH4的平均排放速率(1.010ngCH4·g-1DM·h-1)是10～30℃时平均排放速率(0.255ngCH4·g-1DM·h-1)的3.96倍.增温对柑橘和杉木CH4排放速率的影响显著高于其他4种树木.培养时间对叶片排放CH4速率有显著影响,温度胁迫对树木排放CH4的影响受植物活性的控制.在低温或高温条件下,树木干叶均不能排放CH4.高温胁迫对树木叶片排放CH4有重要影响,全球变暖可能增加植物的CH4排放.     

大兴安岭多年冻土区两种水体温室气体浓度动态与冬季储存特征

北方内陆水体是温室气体排放的热点,对量化区域碳收支起重要作用,但其排放的季节变化尚不清楚。观测了大兴安岭多年冻土区府库奇河及其改道形成的牛轭湖(演替晚期)冻结期冰层中储存的二氧化碳(CO₂)和甲烷(CH₄)浓度,并比较了两种水体中CO₂和CH₄浓度在三个不同时期(冻结期、非冻结期、春季融化)的差异。结果表明：两种水体CO₂和CH₄浓度季节变化存在差异。牛轭湖在冻结期水体中CO₂和CH₄浓度最高,有明显的冰下积累现象,其中CH₄浓度平均值为(2.21±0.54)μmo/L,分别是非冻结期和春季融化期水体CH₄浓度的5倍和14倍。河流水体中CO₂和CH₄浓度最高出现在春季融化期,显著高于非冻结期和冻结期(P<0.05)。水中CO₂和CH₄浓度受多种环境因子的影响,与可溶性有机碳(D...     

美国俄亥俄州人工河滨湿地甲烷排放

2008年11月-2009年10月,在美国俄亥俄州哥伦布市Olentangy河河滨湿地,运用静态箱·气相色谱法对比研究了不同水文模式和植被生长状况下2种植被类型(人工植被和自然植被)淡水河滨恢复湿地甲烷(CH4)排放的时空规律,探讨了湿地土壤温度、水文条件、植被和土壤碳含量等因子对CH4排放的影响.结果表明,人工植被和自然植被湿地CH4排放通量均有明显的季节变化规律,但自然植被的淡水湿地CH4排放量仍明显高于人工植被湿地的排放量,其年排放量分别为68和114gCH4-C· m-2·a-1(P＜0.05),这是由于自然植被湿地相对于人工植被湿地有着更高的累积生产力.在2个实验湿地中,淹没深水区比干湿交替区有更高的CH4排放量,CH4排放通量的中值(平均值)分别为4.7(59.9)和0.09( 1.17)mg·m-2·h-1(P＜0.01),波动的水文相对于静止水文条件可减少CH4排放量.并且,实验湿地CH4排放通量与土壤温度和土壤有机碳含量有一定的相关性.因此,可通过对湿地进行适当的植物配置和水文条件等设计和管理措施有效地减少CH4排放.     

遮阴对米槠和杉木原位排放甲烷的影响

尽管植物在有氧环境是否有氧排放甲烷(CH4)一直存在很大的争议,但越来越多的研究证实植物自身可以排放CH4,而光照是影响植物排放CH4的重要因素。利用13C同位素标记技术结合盆栽实验,探讨了米槠和杉木叶片原位排放CH4的来源及其对太阳光照和遮阴处理的响应。结果表明,标记米槠和杉木叶片的碳稳定同位素13C值分别比未标记的高128.9和71.1倍;密封标记米槠和杉木叶片2h后的δ13CH4值分别比0h时高21.1倍和28.2倍,而未标记米槠和杉木在密封0h与2h时的δ13CH4值之间均没有显著差异,这证实了米槠和杉木排放的CH4主要源于他们自身。自然光照下,杉木的平均CH4排放速率比米槠的平均CH4排放速率高29%。自然光照下的米槠和杉木的CH4排放速率具有相同的波动规律;遮阴对米槠和杉木的CH4排放的影响不同,遮阴处理米槠的CH4排放速率显著低于自然光照处理,平均低23%;遮阴处理杉木的平均CH4排放速率与自然光照处理的没有显著差异,但在遮阴处理5d之后,其CH4排放速率比自然光照下的高71%,之后其CH4排放速率急剧下降,且明显低于自然光照下的CH4排放速率。以上结果表明,太阳光照促进了植物排放CH4的速率。     

华南丘陵地区农林复合生态系统晚稻田甲烷和氧化亚氮排放

采用静态箱-气相色谱法对晚稻田甲烷(CH4)和氧化亚氮(N2O)排放进行田间原位测定。结果表明,有植株参与的稻田CH4排放通量季节变化与地下5cm温度呈显著正相关关系。稻田CH4和N2O季节平均排放通量在有植株参与时分别为1.16±0.38mgm-2h-1和42.33±20.00μgm-2h-1,而无植株参与的分别为0.15±0.11mgm-2h-1和51.69±15.87μgm-2h-1。水稻种植对CH4的排放影响较大,对N2O的排放影响较小,有植株参与的稻田CH4平均排放量显著高于无植株参与的稻田,N2O的平均排放量无显著差异。     

No Longer a Paradox: The Interaction Between Physical Transport and Biological Processes Explains the Spatial Distribution of Surface Water Methane Within and Across Lakes

Lakes play an important role in the global carbon cycle, emitting significant amounts of the carbonic greenhouse gases, CO₂ and methane (CH₄). Nearly all lake studies have reported oxygenated surface waters oversaturated with (and thus continuously emitting) CH₄, yet no consistent explanation exists to account for why CH₄, which is produced in anoxic zones and consumed in the presence of oxygen, remains in oxic waters across the range of lake sizes. Here, we developed a physical model that defines the spatial CH₄ distribution in the surface waters of lakes as a function of CH₄ transport from the littoral zone including air–water gas exchange, and tested this in a set of 14 lakes that ranged widely in size (0.07–19,000 km²). Although the model adequately resolved the overall CH₄ decline within a lake relative to distance from shore across the range of lake sizes, discrepancies between observations and predictions suggest that other processes modulate surface CH₄ distributions. Coupled trends in the stable carbon isotopic signature of CH₄ further indicate that the spatial pattern in 30% of the lakes was dominated by a net loss via oxidation, whereas a net input of ¹³C-depleted CH₄ dominated the spatial pattern in 70% of the lakes, suggesting the predominance of pelagic CH₄ production in the oxic epilimnia of these lakes. The spatial patterns imposed by the interaction between physical and biological processes may result in a size-dependent underestimation of whole-lake CH₄ emissions when based on center samples. Whereas the actual contributions of oxidation and eplimnetic CH₄ production are still not well understood, our results demonstrate that the ubiquitous CH₄ oversaturation observed in most lakes can be explained through the interaction between horizontal transport of littoral CH₄, air–water gas exchange and the balance between epilimnetic CH₄ oxidation and production.     

Methane (CH4) release from littoral wetlands of Boreal lakes during an extended flooding period

Lake littoral zones have a transitional nature and dynamic conditions, which are reflected in their CH₄ emissions. Thus, detailed studies are needed to assess the littoral CH₄ emissions in a regional scale. In this study, CH₄ fluxes were followed during the ice‐free seasons in 1998 and 1999 by using the static chamber method in the littoral zone of two lakes in Finland. An exceptionally high water level in 1998 caused an unusually long inundation in otherwise ephemerally flooded zone. The flooding was normal in year 1999. The factors controlling CH₄ emissions were examined and statistical response functions were constructed. Further, the effect of extended flooding on the littoral CH₄ budged was estimated. The methane flux was primarily regulated by the water level in grass and sedge dominated eulittoral zone, but not in infralittoral reed and water lily stands. Methane emissions in the sedge dominated zone decreased significantly, when the flood was high enough to submerge the venting structures of the plants. Besides water level, sediment temperature determined CH₄ emission. The cumulative CH₄ emissions from the whole littoral wetlands in wet year were 1.1 times (L. Kevätön), or 0.61 and 0.79 times (L. Mekrijärvi) those in dry year. The crucial factor was the discrepancy between the exceptional and the average water level. The extension of inundated area does not necessarily increase CH₄ emissions if the flood reaches infrequently inundated areas, which apparently have low CH₄ production potential. This is the case especially, if the emissions in lower zones simultaneously decrease due to high water level. Our study analyses these complex responses between CH₄ emissions and water level.     

The biogeochemical cycle of methane in the coastal zone and littoral of the Kandalaksha Bay of the White Sea

Microbiological and biogeochemical investigations of the processes of methane production (MP) and methane oxidation (MO) in the coastal waters and littoral of the Kandalaksha Bay of the White Sea were carried out. The studies were conducted in the coastal zones and in the water areas of the Kandalaksha Preserve, Moscow University White Sea Biological Station, and Zoological Institute (RAS) Biological Station in August, 1999, 2000, and 2001 and in March, 2001. The rate of CO2 assimilation in the shallow and littoral sediments was 35-27800 microg C/(dm3 day) in summer and 32.8-88.9 microg C/(dm3 day) in winter. The maximal rates of MP were observed in the littoral sediments in the zone of macrophyte decomposition, in local depressions, and in the estuary of a freshwater creak (up to 113 microl/(dm3 day)). The maximal level of MO was observed in the shallow estuarine sediments (up to 2450 microl/(dm3 day)). During the winter season, at the temperature of -0.5 to 0.5 degrees C, the MP rate in the littoral sediments was 0.02-0.3 microl/(dm3 day), while MO rate was 0.06-0.7 microl/(dm3 day). The isotopic data obtained indicate that the C(org) of the mats and of the upper sediment layers is enriched with the heavy 13C isotope by 1-4 per thousand as compared to the C(org) of the suspension, comprised on 33.5-34.3% of phytoplankton. A striking difference was found between the levels of methane emission by the typical littoral microlanscapes. In fine sediments, the average emission was 675 microl CH4/(m2 day), in the stormy discharge stretch sediments it was 1670 microl CH4/(m2 day), and under the stones and in silted pits, 1370 microl CH4/(m2 day). The calculation performed with consideration of the microlandscape areas with a high production allowed the CH4 production of 1 km2 of the littoral to be estimated as 192-300 1 CH4/(km2 day).     

Late Wenlock (Middle Silurian) global Bioevent: Possible chemical cause for mass graptolite mortalities

Graptolites nearly became extinct in the latest Wenlock in all preserved stratigraphic sequences of this age. Graptolite mortalities occurred along the western coast of Laurentia and at sites that surrounded the Proto‐Tethys. Graptolite mass mortalities took place among deep‐water, open ocean dwelling organisms. After the mass mortalities, only the Pristiograptus dubius group and retiolids surface or near‐surface dwellers, survived. For a period of time, little speciation or diversification occurred. The base of the Ludlow is marked by diversification, with appearances of S. colonus, M. nilssoni and other groups which occur in near surface waters. None of the extensive plate movements postulated for the Silurian readily explain the mass extinctions that occurred. During the Silurian, global temperatures were warmer than present and atmospheric oxygen concentrations were lower, creating extensive oceanic anoxia. Below the oxygenated surface layers of the ocean, was an anoxic, non‐sulfidic zone (i.e. nitrate‐reducing) above a sulfidic zone. Graptolites lived over a range of depth from the oxygenated zone to either near or in the nitrate‐reducing zones. As the oxygen concentration declined through the Silurian, the depth of the oxic zone would have become shoaler with expanding anoxia. Late Wenlock graptolites that were unable to migrate to shallower depths, living in borderline oxygen conditions, could have been killed, resulting in the mortalities of the late Wenlock. Only those graptolites that were surface dwellers survived, adapted and reradiated.     

Depth-discrete metagenomics reveals the roles of microbes in biogeochemical cycling in the tropical freshwater Lake Tanganyika

Lake Tanganyika (LT) is the largest tropical freshwater lake, and the largest body of anoxic freshwater on Earth’s surface. LT’s mixed oxygenated surface waters float atop a permanently anoxic layer and host rich animal biodiversity. However, little is known about microorganisms inhabiting LT’s 1470 meter deep water column and their contributions to nutrient cycling, which affect ecosystem-level function and productivity. Here, we applied genome-resolved metagenomics and environmental analyses to link specific taxa to key biogeochemical processes across a vertical depth gradient in LT. We reconstructed 523 unique metagenome-assembled genomes (MAGs) from 34 bacterial and archaeal phyla, including many rarely observed in freshwater lakes. We identified sharp contrasts in community composition and metabolic potential with an abundance of typical freshwater taxa in oxygenated mixed upper layers, and Archaea and uncultured Candidate Phyla in deep anoxic waters. Genomic capacity for nitrogen and sulfur cycling was abundant in MAGs recovered from anoxic waters, highlighting microbial contributions to the productive surface layers via recycling of upwelled nutrients, and greenhouse gases such as nitrous oxide. Overall, our study provides a blueprint for incorporation of aquatic microbial genomics in the representation of tropical freshwater lakes, especially in the context of ongoing climate change, which is predicted to bring increased stratification and anoxia to freshwater lakes.Subject terms: Biogeochemistry, Limnology, Microbial ecology, Freshwater ecology     

内蒙古草甸草原CH4和N2O排放通量的时间变异

 1998年6月1日、7月2日、8月3日和9月1日用静态箱-气相色谱法对内蒙古锡林河流域草甸草原CH4和N2O排放通量的昼夜观测表明,天然草原是N2O的源、CH4的汇,其排放和吸收具有明显的昼夜变化规律。4次昼夜观测的结果还表明,草甸草原排放N2O和吸收CH4的能力具有强烈的季节变化规律     

Hydrology is reflected in the functioning and community composition of methanotrophs in the littoral wetland of a boreal lake

In lake ecosystems a major proportion of methane (CH(4) ) emissions originate from the littoral zone, which can have a great spatial variability in hydrology, soil quality and vegetation. Hitherto, spatial heterogeneity and the effects it has on functioning and diversity of methanotrophs in littoral wetlands have been poorly understood. A diagnostic microarray based on the particulate methane monooxygenase gene coupled with geostatistics was used to analyse spatial patterns of methanotrophs in the littoral wetland of a eutrophic boreal lake (Lake Kev?t?n, Eastern Finland). The wetland had a hydrology gradient with a mean water table varying from -8 to -25 cm. The wettest area, comprising the highest CH(4) oxidation, had the highest abundance and species richness of methanotrophs. A high water table favoured the occurrence of type Ib methanotrophs, whereas types Ia and II were found under all moisture conditions. Thus the spatial heterogeneity in functioning and diversity of methanotrophs in littoral wetlands is highly dependent on the water table, which in turn varies spatially in relation to the geomorphology of the wetland. We suggest that changes in water levels resulting from regulation of lakes and/or global change will affect the abundance, activity and diversity of methanotrophs, and consequently CH(4) emissions from such systems.     

Does predation risk influence habitat use by northern redbelly dace Phoxinus eos at different spatial scales?

This study investigated the relationship between spatial variations in predation risk and abundance of northern redbelly dace Phoxinus eos at both macroscale (littoral v. pelagic zones) and microscale (structured v. open water habitats in the littoral zone) of Canadian Shield lakes. Minnow traps were placed in both structured and open water habitats in the littoral zone of 13 Canadian Shield lakes, and estimates of the relative predation risk of P. eos in both the pelagic and the littoral zones were obtained from tethering experiments. Results showed that (1) the mean abundance of P. eos in the littoral zone was positively correlated with the relative predation risk in the pelagic zone, (2) P. eos preferentially used structured over open water habitats in the littoral zone and (3) this preference was not related to the relative predation risk in the littoral zone but decreased as the relative predation risk increased in the pelagic zone. At the lake level, these results support the hypothesis that P. eos enter the littoral zone to avoid pelagic piscivores. At the littoral zone level, the results do not necessarily contradict the widely accepted view that P. eos preferentially use structured over open habitats to reduce their predation risk, but suggest that flexibility in antipredator tactics ( e.g. shelter use v. shoaling) could explain the spatial distribution of P. eos between structured and open water habitats.     

Intensity of the microbiological processes of the methane cycle in different types of Baltic lakes

The intensity of the microbiological processes of methane formation (MF) and methane oxidation (MO) was determined in the sediments and water of different types of Baltic lakes. The emission of methane from the lake sediments and methane distribution in the water column of the lakes were studied as functions of the lake productivity and hydrologic conditions. During summers, the intensity of MF in the lake sediments and waters varied from 0.001 to 106 ml CH4/(dm3 day) and from 0 to 3.2 ml CH4/(1 day), respectively, and the intensity of MO in the sediments and water varied from 0 to 11.2 ml CH4/(dm3 day) and from 0 to 1.1 ml CH4/(1 day), respectively. The total methane production (MP) in the lakes varied from 15 to 5000 ml CH4/(m2 day). In anoxic waters, the MP comprised 9-18% of the total PM in the lakes. The consumption of organic carbon for methanogenesis varied from 0.03 to 9.7 g/(m2 day). The role of the methane cycle in the degradation of organic matter in the lakes increased with their productivity.