陆地生态系统氮沉降增加的生态效应

 人类活动在全球范围内极大地改变着氮素从大气向陆地生态系统输入的方式和速率，人为固定的氮素正在不断积累，并对生态系统的结构和功 能产生显著影响。该文从以下几个方面综述了大气氮沉降增加对陆地生态系统的影响：1)氮输入增加可能影响植物生产力和生态系统碳蓄积能 力，生态系统响应的方向和程度取决于系统的初始氮状况(氮限制或氮饱和)以及当地的植被和土壤特征；2)持续氮输入有可能改变土壤氮循环 过程，降低土壤固持氮的能力，甚至导致土壤酸化、盐基离子损耗，进而影响到土壤有机碳的分解；3)高的氮沉降速率和持续氮输入都可能加 速含氮痕量气体的释放，但其影响程度受生态系统初始状态的影响(例如磷限制和氮限制)；4)氮沉降增加会影响生态系统的物种丰富度、植物 群落结构和动态，促进森林扩张，改变菌根真菌的物种多样性；5)持续氮输入带来的植物群落结构和植物生理特征的变化可能影响昆虫取食特 性，进而通过食物链改变生态系统的营养结构；6) 氮沉降增加对生态系统的影响并不是孤立存在的，它与CO₂浓度升高和O₃浓度变化有协同作 用，但难以从其协同效应中区分出各自的影响。最后，该文总结了我国的氮沉降研究现状，并对今后的研究前景提出了展望。     

森林土壤氮素转换及其对氮沉降的响应

近几十年人类活动向大气中排放的含氮化合物激增 ,并引起大气氮沉降也成比例增加。目前 ,氮沉降的增加使一些森林生态系统结构和功能发生改变 ,甚至衰退。近 2 0 a欧洲和北美有关氮沉降及其对森林生态系统的影响方面的研究较多 ,而我国少有涉及。森林土壤氮素转换是森林生态系统氮素循环的一个重要的组成部分 ,而矿化、硝化和反硝化作用是其核心过程 ,氮沉降作为驱动因子势必改变森林土壤氮素转换速度、方向和通量。根据国外近 2 0 a有关研究 ,首先介绍了森林土壤氮素转换过程和强度 ,论述森林土壤氮素在生态系统氮素循环中的作用 ,然后在此基础上 ,介绍了氮沉降对森林土壤氮素循环的研究途径 ,探讨了氮沉降对森林土壤氮素矿化、硝化和反硝化作用的影响及其机理     

北京东灵山大气氮沉降水平及变化特征

城市人为成因的气态活性氮排放影响空气质量，导致周边的陆地生态系统大气氮输入量持续增加。然而，陆地生态系统大气活性氮特别是溶解态无机氮(DIN)和溶解态有机氮(DON)的同步观测仍然较为缺乏，影响氮沉降生态效应的全面、准确评估。本研究观测了北京东灵山森林生态系统定位研究站2019年6月至2020年1月每周的混合沉降中铵态氮(NH₄⁺-N)、硝态氮(NO₃^--N)和总溶解态氮(TDN)浓度，计算了DON浓度和各形态氮的沉降通量，分析了它们的月际和干湿季差异及其变化机制。结果表明：该站点大气沉降中NH₄⁺-N、NO₃^--N、DON和TDN体积加权平均浓度分别为1.45±0.04、0.70±0.01、1.81±0.66和3.96±0.65 mg N·L^-1,TDN年沉降通量为25.00 kg N·hm^-2·a^-1,NH₄^+<...     

报春巨苔的野外回归研究

中国科学家研究发现,大气氮沉降通过诱导土壤酸化效应,引起富氮森林生态系统的植物多样性显著减少。过去一般认为,大气氮沉降将降低氮限制生态系统的生物多样性而对富氮生态系统的影响甚微,人们认为在氮限制的生态系统中,氮的增加更有利于喜氮植物的生长,使其在竞争中处于优势;而在富氮的生态系统中,氮的增加对植物生长的影响不大。新研究不仅填补了国际上热带和亚热带区域氮沉降对森林植物多样性影响研究的空白,同时表明了氮沉降可能威胁“富氮”森林的植物多样性。     

森林生态系统碳循环对全球氮沉降的响应

森林土壤和植被储存着全球陆地生态系统大约46%的碳,在全球碳平衡中起着非常重要的作用。过去几十年来,森林生态系统的碳循环和碳吸存受到了全球氮沉降的深刻影响,因为氮沉降改变了陆地生态系统的生产力和生物量积累。以欧洲和北美温带森林区域开展的研究为基础,综述了氮沉降对植物光合作用、土壤呼吸、土壤DOM及林木生长的影响特征和机理,探讨了森林生态系统碳动态对氮沉降响应的不确定性因素。热带森林C、N循环与大部分温带森林不同,人为输入的氮对热带生态系统过程的影响也可能不同,因此指出了在热带地区开展碳氮循环耦合研究的必要性和紧迫性。     

长期氮添加对草甸草原生态系统氮库的影响

大气氮沉降增加深刻影响生态系统物种多样性、生产力及其稳定性,研究草原生态系统N库如何响应不断增加的大气氮沉降至关重要。本研究在内蒙古额尔古纳草甸草原开展刈割和不同水平外源氮添加试验,设置6个氮添加水平: 0、2、5、10、20和50 g·m^-2·a^-1,同时设置刈割处理,分为刈割和不刈割2个水平。在连续处理的第7年,采集群落中优势植物地上部分、群落根、地表凋落物和0～100 cm分层土壤样品,测定N含量并计算N库储量。结果表明: 氮添加显著增加植物地上部分和凋落物N含量,以及羊草、植物群落和凋落物的N库及生态系统N库总量。刈割处理显著增加羊草叶片和凋落物N含量,降低羊草、植物群落和凋落物N库,但并不改变它们对氮添加的响应格局。此外,刈割和氮添加对植物群落N库存在显著的交互作用。在不刈割处理下,高水平氮添加使更多的氮储存在凋落物中等待分解,植物群落N库的饱和阈值出现在10 g·m^-2·a^-1;在刈割处理下,植物群落N库表现为随氮添加量增加而不断增加,并且在相同水平氮添加条件下刈割后进入到植物群落N库中的氮更多。刈割可以缓解氮沉降不断增加对生物多样性和生态系统稳定性造成的不利影响,并可以在一定程度上推迟氮沉降增加引起的生态系统氮饱和的发生。     

1961-2010年中国区域氮沉降时空格局模拟研究

由于人类活动的干扰,近年来,通过沉降和施肥形式进入陆地生态系统的氮素持续增加,众多研究表明,中国已经成为继欧洲和北美之后的第三大氮沉降区。氮与陆地生态系统生物地球化学循环的一系列过程都相互联系,碳循环及其格局也受到氮的影响,因此大气氮沉降的变化受到广泛关注,探明区域大气氮沉降的时空格局对评估氮沉降对陆地生态系统碳循环的影响具有重要意义。构建了一个基于降水、能源消费和施肥数据的氮沉降时空格局模拟方法,通过与观测数据的比较说明该模拟方法能够较好地模拟氮沉降的时空变化,在此基础上,利用该方法模拟了1961-2010年中国区域氮沉降的时空格局。结果表明:(1)1961-2010年中国区域年平均氮沉降速率为0.81 g N m^-2 a^-1,由20世纪60年代的0.31 g N m^-2 a^-1增加到21世纪初的1.71 g N m^-2 a^-1,年增长率为0.04 g N m^-2 a^-1。总氮沉降量由20世纪60年代的2.85 TgN/a增加至15.68 TgN/a。(2)NH_x-N的沉降速率大约是NO_y-N的4倍,是主要的氮沉降形式。1961-2010年我国湿沉降平均速率为0.63 g N m^-2 a^-1,是干沉降速率(0.17 g N m^-2 a^-1)的3.63倍,是氮素进入陆地生态系统的重要途径。(3)在空间上,我国的大气氮沉降速率呈现出由东南向西北梯度递减的格局,华北、华中和东北的农田是氮沉降速率最大的区域,同时也是氮沉降速率增长最快的区域。     

森林土壤呼吸对氮硫沉降的响应及机制

在氮沉降和硫沉降增加的背景下,土壤氮素可利用性增加和土壤酸化是多数陆地生态系统正在经历的两个重要生态学过程。氮沉降和硫沉降的增加以及两者之间的耦合作用对土壤呼吸会产生扰动,进而很大程度上可能影响到森林生态系统的碳收支。本文综述了氮沉降和硫沉降对土壤呼吸的影响及机制,分析了氮沉降与硫沉降的耦合作用,指出了目前森林生态系统土壤呼吸对氮沉降和硫沉降响应研究的薄弱环节以及今后相关领域的重点研究方向。     

土壤呼吸对降雨变化和氮沉降交互作用响应的研究进展

土壤呼吸作为陆地生态系统碳循环的关键过程,对大气CO₂浓度变化有直接影响。研究其如何响应降雨变化、氮沉降增加等全球变化因子,成为近年全球变化领域的热点与难点。与土壤呼吸响应降雨变化或氮沉降增加单个因子相比,研究土壤呼吸对这两个因子交互作用的响应更接近真实的自然环境,可更准确地预估未来土壤碳排放的变化趋势。目前,相关研究涉及全球不同的陆地生态系统,从土壤、微生物和植物层面对其响应机理进行揭示。本文从土壤呼吸及其组分、相关的土壤性质、微生物及植物因素方面,较全面地梳理了不同陆地生态系统土壤呼吸响应降雨变化和氮沉降增加交互作用的研究进展,指出了现有研究中的不足及今后需加强的研究方向,以期为进一步揭示土壤呼吸对降雨变化和氮沉降增加交互作用的响应规律及机制提供参考。     

增加降水及大气氮沉降对黄淮海平原弃耕地地表节肢动物的影响

作为全球变化的重要驱动因子,日益频繁且不断加剧的降水格局变化及大气氮沉降正在对我们赖以生存的陆地生态系统造成重要影响.然而,过去关于全球变化对陆地生态系统影响的研究主要集中于地上植物群落,而对于土壤动物,特别是地表节肢动物的研究相对较少.本文采用控制试验的方法,研究增加降水及氮沉降对我国黄淮海平原弃耕地生态系统地表节肢动物的影响.结果表明: 增加降水使地表节肢动物的数量显著增加了66.9%,使整个群落的类群数显著增加了27.8%.氮沉降对地表节肢动物的种群密度及类群数均无影响,但显著增加了群落中蚁科动物的数量,显著降低了跳虫的数量.本研究结果表明,降水格局的变化是驱动中国北方平原弃耕地生态系统地表节肢动物群落结构变化的重要因子,其影响机制主要是通过影响土壤湿度及植物生长实现的.     

Symptoms of nitrogen saturation in two central Appalachian hardwood forest ecosystems

By synthesizing more than twenty years of research at the Fernow Experimental Forest, we have documented 7 symptoms of nitrogen saturation in two adjacent watersheds. The symptoms include: 1) high relative rates of net nitrification, 2) long-term increases in stream-water concentrations of nitrate and base cations, 3) relatively high nitrate concentrations in solution losses, 4) little seasonal variability in stream-water nitrate concentrations, 5) a high discharge of nitrate from a young aggrading forest, 6) a rapid increase in nitrate loss following fertilization of a young aggrading forest, and 7) low retention of inorganic nitrogen when compared with other forested sites. These data support current conceptual models of nitrogen saturation and provide a strong, and perhaps the best, example of nitrogen saturation in the United States.     

Effect of meteorology and nutrient load on oxygen depletion in a Danish micro-tidal estuary

In a detailed analysis of oxygen saturation in a shallow Danish estuary it was possible to separate the effect of meteorological forcings (i.e. wind and solar radiation) and nutrient loads on oxygen depletion in bottom water. Regression analysis showed that oxygen saturation tied to nitrogen load rather than to phosphorus load. During summer periods of stratification the oxygen saturation could be attributed to the time elapsed after the onset of stratification and the accumulated nitrogen loading 10 month prior to measurement. Using a 10-year meteorological database and an empirical model it was calculated that a 25% reduction in nitrogen loading would reduce the number of days with severe oxygen depletion (i.e. <15% of saturation) by more than 50%.     

Nitrogen Retention, Removal, and Saturation in Lotic Ecosystems

Increased nitrogen (N) loading to lotic ecosystems may cause fundamental changes in the ability of streams and rivers to retain or remove N due to the potential for N saturation. Lotic ecosystems will saturate with sustained increases in the N load, but it is unclear at what point saturation will occur. Rates of N transformation in lotic ecosystems will vary depending on the total N load and whether it is an acute or chronic N load. Nitrogen saturation may not occur with only pulsed or short-term increases in N. Overall, saturation of microbial uptake will occur prior to saturation of denitrification of N and denitrification will become saturated prior to nitrification, exacerbating increases in nitrate concentrations and in N export downstream. The rate of N export to downstream ecosystems will increase proportionally to the N load once saturation occurs. Long term data sets showed that smaller lotic ecosystems have a greater capacity to remove in-stream N loads, relative to larger systems. Thus, denitrification is likely to become less important as a N loss mechanism as the stream size increases. There is a great need for long-term studies of N additions in lotic ecosystems and clear distinctions need to be made between ecosystem responses to short-term or periodic increases in N loading and alterations in ecosystem functions due to chronic N loading.     

氮输入对植物光合固碳的影响研究进展

植物光合固碳(C)是生物固C的重要途径和生态系统C循环中的重要环节。在全球环境变化背景下,研究氮(N)输入对植物光合固C的影响,对于更好的认识C、N循环过程及生态系统对全球变化的响应过程等具有重要意义。N输入是否能够增加植物固C取决于生态系统类型以及生态系统的N饱和度;草原和湿地生态系统N输入的临界负荷值较高,干旱、半干旱荒漠地区较低;N输入可能改变植物光合固C在各器官的分配,主要由植物生理、自身生长节律和环境养分等决定。由于物种和生态系统类型的差异,N输入对植物固C的影响仍具有很大的不确定性,目前缺乏准确、定量表达N输入对生态系统光合和C同化物分配影响的数学表达方法和过程算法。未来应着重加强N输入下C同化物分配的生物地球化学模型和N、P富集下植物光合固C耦合模型研究,并应用同位素标记和分子生物学技术,从生态系统角度综合探讨N输入下植物光合固C的分配和转化特征。     

Growth and root nodule nitrogenase activity of Pisum sativum as influenced by transpiration

The influence of shoot transpiration on the rates of growth and nitrogen fixation was investigated in Pisum sativum L. cv. Rondo. In short term experiments, rates of transpiration and acetylene reduction of intact plants were measured simultaneously, using air-tight perspex vessels enclosing the basal part of the nodulated root. In long term experiments, accumulation of dry matter and reduced nitrogen in the plant were determined as well. Transpiration rate changed diurnally and was varied by manipulating the vapour saturation deficit or the flow rate of the air in the growth cabinet. The rate of acetylene reduction declined after subjecting intact plants to high transpiration rates. This decline was accompanied by a desiccation of the root nodules. Dry matter and reduced nitrogen accumulation were not affected by transpiration rate. At low transpiration rate reduced nitrogen content of the root nodules was higher than at high transpiration rate. However, in these nodules the rate of acetylene reduction was not significantly affected. It is concluded that the nitrogenase activity of pea root nodules is insensitive to changes in the flow rate and the organic N concentration of the xylem sap within a wide range of transpiration conditions under the applied growth conditions.     

15N自然丰度法在陆地生态系统氮循环研究中的应用

随着氮沉降的不断增加以及人们对全球变化问题的日益关注, 稳定同位素技术在全球变化研究中得到广泛的应用。因为植物和土壤的氮同位素组成记录了氮循环影响因子的综合作用, 并且具有测量简单以及不受取样时间和空间限制的优点, 所以氮同位素自然丰度法被用于氮循环的研究中。该文从氮循环过程中植物和土壤的氮分馏入手, 总结国内外相关文献, 阐述了植物和土壤氮自然丰度在预测生态系统氮饱和和氮循环长期变化趋势中的应用; 总结了利用树轮δ ¹⁵N法研究氮循环过程中应该注意的事项以及目前尚未解决的问题。     

AtDUR3 represents the major transporter for high-affinity urea transport across the plasma membrane of nitrogen-deficient Arabidopsis roots

Despite the fact that urea is a ubiquitous nitrogen source in soils and the most widespread form of nitrogen fertilizer used in agricultural plant production, membrane transporters that might contribute to the uptake of urea in plant roots have so far been characterized only in heterologous systems. Two T-DNA insertion lines, atdur3-1 and atdur3-3, that showed impaired growth on urea as a sole nitrogen source were used to investigate a role of the H+/urea co-transporter AtDUR3 in nitrogen nutrition in Arabidopsis. In transgenic lines expressing AtDUR3-promoter:GFP constructs, promoter activity was upregulated under nitrogen deficiency and localized to the rhizodermis, including root hairs, as well as to the cortex in more basal root zones. Protein gel blot analysis of two-phase partitioned root membrane fractions and whole-mount immunolocalization in root hairs revealed the plasma membrane to be enriched in AtDUR3 protein. Expression of the AtDUR3 gene in nitrogen-deficient roots was repressed by ammonium and nitrate but induced after supply of urea. Higher accumulation of urea in roots of wild-type plants relative to atdur3-1 and atdur3-3 confirmed that urea was the substrate transported by AtDUR3. Influx of 15N-labeled urea in atdur3-1 and atdur3-3 showed a linear concentration dependency up to 200 microM external urea, whereas influx in wild-type roots followed saturation kinetics with an apparent Km of 4 microM. The results indicate that AtDUR3 is the major transporter for high-affinity urea uptake in Arabidopsis roots and suggest that the high substrate affinity of AtDUR3 reflects an adaptation to the low urea levels usually found in unfertilized soils.     

Mechanisms of plant species impacts on ecosystem nitrogen cycling

Plant species are hypothesized to impact ecosystem nitrogen cycling in two distinctly different ways. First, differences in nitrogen use efficiency can lead to positive feedbacks on the rate of nitrogen cycling. Alternatively, plant species can also control the inputs and losses of nitrogen from ecosystems. Our current understanding of litter decomposition shows that most nitrogen present within litter is not released during decomposition but incorporated into soil organic matter. This nitrogen retention is caused by an increase in the relative nitrogen content in decomposing litter and a much lower carbon‐to‐nitrogen ratio of soil organic matter. The long time lag between plant litter formation and the actual release of nitrogen from the litter results in a bottleneck, which prevents feedbacks of plant quality differences on nitrogen cycling. Instead, rates of gross nitrogen mineralization, which are often an order of magnitude higher than net mineralization, indicate that nitrogen cycling within ecosystems is dominated by a microbial nitrogen loop. Nitrogen is released from the soil organic matter and incorporated into microbial biomass. Upon their death, the nitrogen is again incorporated into the soil organic matter. However, this microbial nitrogen loop is driven by plant‐supplied carbon and provides a strong negative feedback through nitrogen cycling on plant productivity. Evidence supporting this hypothesis is strong for temperate grassland ecosystems. For other terrestrial ecosystems, such as forests, tropical and boreal regions, the data are much more limited. Thus, current evidence does not support the view that differences in the efficiency of plant nitrogen use lead to positive feedbacks. In contrast, soil microbes are the dominant factor structuring ecosystem nitrogen cycling. Soil microbes derive nitrogen from the decomposition of soil organic matter, but this microbial activity is driven by recent plant carbon inputs. Changes in plant carbon inputs, resulting from plant species shifts, lead to a negative feedback through microbial nitrogen immobilization. In contrast, there is abundant evidence that plant species impact nitrogen inputs and losses, such as: atmospheric deposition, fire‐induced losses, nitrogen leaching, and nitrogen fixation, which is driven by carbon supply from plants to nitrogen fixers. Additionally, plants can influence the activity and composition of soil microbial communities, which has the potential to lead to differences in nitrification, denitrification and trace nitrogen gas losses. Plant species also impact herbivore behaviour and thereby have the potential to lead to animal‐facilitated movement of nitrogen between ecosystems. Thus, current evidence supports the view that plant species can have large impacts on ecosystem nitrogen cycling. However, species impacts are not caused by differences in plant quantity and quality, but by plant species impacts on nitrogen inputs and losses.     

棉花叶片氮含量的空间分布与光合特性

在棉花生长旺季,将冠层按高度分多层测定了田间叶片含氮量和叶片净光合速率对光合有效辐射通量密度的响应(光响应曲线,Pn-PPFD response curve)及相应的生物指标.结果表明,各层叶片氮含量与光合作用关系密切,各层平均值大小依次为上层＞中层＞下层,对应层叶片的最大净光合速率Pmax、表观暗呼吸速率Rd、光补偿点LCP及光饱和点LSP均从上到下依次递减,与氮含量分布一致,而表观光合量子效率AQY则略有不同;氮含量的指数衰减系数 kn =0.762(R2=0.593),根据观测结果,棉田叶片氮含量(N)空间分布可以用相对累积叶面积指数(Lc/Lt)为自变量的指数方程来模拟,从而为建立光合作用机理模型与进行生产力奠定基础.     

鼎湖山亚热带常绿针阔叶混交林凋落物及矿质氮输入对土壤有机碳分解的影响

2010年7-12月,选取鼎湖山国家级自然保护区亚热带针阔叶混交林,采用全因子控制试验,研究不同类型的凋落物(针叶和阔叶凋落物)添加及氮处理(加氮模拟氮饱和、减氮模拟根吸收)对表层(0～10 cm)和下层(20～30 cm)土壤有机质分解(呼吸)的影响.结果表明:2010年7-11月间,两种凋落物的添加使土壤-凋落物系统的呼吸速率显著增加,但这种影响在12月消失.减氮和加氮处理均显著增加了土壤-凋落物系统的呼吸.叶凋落物短期内完全分解,对土壤碳分解和积累的影响十分有限,可能不是该系统中土壤有机质的主要来源.通过减少土壤可利用氮模拟根系对氮的吸收能够明显促进土壤有机质的分解.