Enhanced evapotranspiration was observed during extreme drought from Miscanthus,opposite of other crops

The impact of extreme drought and heat stress that occurred in the Midwestern U.S. in 2012 on evapotranspiration (ET), net ecosystem productivity (NEP), and water‐use efficiency (WUE) of three perennial ecosystems (switchgrass, miscanthus, prairie) and a maize/soybean agroecosystem was studied as part of a long‐term experiment. Miscanthus had a slower initial response but an eventually drastic ET as drought intensified, which resulted in the largest water deficit among the crops. The substantially higher ET at peak drought was likely supplied by access to deep soil water, but suggests that stomatal conductance of miscanthus during the drought may respond differently than the other ecosystems, consistent with an anisohydric strategy. While there was a discrepancy in the water consumption of maize and switchgrass/prairie in the early time of drought, all these ecosystems followed a water‐saving strategy when drought intensified. The gross primary production (GPP) of miscanthus dropped, but was reversible, when temperature reached 40 °C and still provided the largest total GPP among the ecosystems. Increased ET for miscanthus during 2012 resulted a large decline in ecosystem WUE compared to what was observed in other years. The biophysical responses of miscanthus measured during an extreme, historic drought suggest that this species can maintain high productivity longer than other ecosystems during a drought at the expense of water use. While miscanthus maintained productivity during drought, recovery lagged associated with depleted soil moisture. The enhanced ET of miscanthus may intensify droughts through increase supply of deep soil moisture to the atmosphere.     

农业生态系统中磷循环的研究进展

1　引　言能量转化和物质循环是农业生态系统最基本的功能特征。1976年在荷兰召开的第一次农业生态系统矿质养分循环研讨会标志着从系统层次研究物流的开始,但物流仍是系统研究的薄弱环节,特别是较高系统层次准确的物流的数量概念更为缺乏[1,2]。生态系统中营养元素的输入、输出状况反映了一个地区生产发展水平的高低和生态系统功能的强弱;而投入、产出的动态变化,则显示了一定时期内营养元素循环的基本规律[3]。在各种水平(如地球、陆地、国家或生态系统)上的有关磷循环的论文也发表了不少,借以阐述各组成部分中磷的数量及其相互间的转化速…     

Seasonal variability in net ecosystem carbon dioxide exchange over a young Switchgrass stand

Understanding carbon dynamics of switchgrass ecosystems is crucial as switchgrass (Panicum virgatum L.) acreage is expanding for cellulosic biofuels. We used eddy covariance system and examined seasonal changes in net ecosystem CO₂ exchange (NEE) and its components – gross ecosystem photosynthesis (GEP) and ecosystem respiration (ER) – in response to controlling factors during the second (2011) and third (2012) years of stand establishment in the southern Great Plains of the United States (Chickasha, OK). Larger vapor pressure deficit (VPD > 3 kPa) limited photosynthesis and caused asymmetrical diurnal NEE cycles (substantially higher NEE in the morning hours than in the afternoon at equal light levels). Consequently, rectangular hyperbolic light–response curve (NEE partitioning algorithm) consistently failed to provide good fits at high VPD. Modified rectangular hyperbolic light–VPD response model accounted for the limitation of VPD on photosynthesis and improved the model performance significantly. The maximum monthly average NEE reached up to ?33.02 ± 1.96 μmol CO₂ m^?2 s^?1 and the highest daily integrated NEE was ?35.89 g CO₂ m^?2 during peak growth. Although large differences in cumulative seasonal GEP and ER were observed between two seasons, total seasonal ER accounted for about 75% of GEP regardless of the growing season lengths and differences in aboveground biomass production. It suggests that net ecosystem carbon uptake increases with increasing GEP. The ecosystem was a net sink of CO₂ during 5–6 months and total seasonal uptakes were ?1128 ± 130 and ?1796 ± 217 g CO₂ m^?2 in 2011 and 2012, respectively. In conclusion, our findings suggest that the annual carbon status of a switchgrass ecosystem can be a small sink to small source in this region if carbon loss from biomass harvesting is considered. However, year‐round measurements over several years are required to assess a long‐term source‐sink status of the ecosystem.     

中国土地利用多功能性动态的区域分析

当前,国际学术界针对土地利用的研究正由土地利用格局变化向土地空间多功能变化及其可持续性的方向发展,其宗旨是确定和度量土地多元化利用所提供的产品、服务和功能,及其带来的环境和社会经济效应,实现对土地利用的科学管理。基于可持续发展三维度的理念及其指标体系,界定并定量评价了我国区域土地利用的10项功能,深入研究了在经济快速发展、生态环境保护紧密相随的过去20a间,各项功能的时空变化特征。研究表明,我国土地多功能性的10项功能中,就业支持功能表现出区域增减不一的特点,生态过程维持功能具有高度的稳定性。健康保障、交通功能、居住家园、生物性土地生产、人工化土地生产、资源供给与维持、污染接收器、景观与文化支持功能在各个区域得到了不断改善与提高,但各个功能变化的强势区和弱势区在时空分布上表现出了很强的区域性特点。区域自然条件禀赋、社会经济条件以及土地利用政策在功能变化中起着关键作用。研究结果揭出中国区域土地多功能性尚存在巨大的提升空间;土地政策应具有系统性、功能针对性和时空针对性,并应关注土地利用功能变化的链发效应。     

Investigating the long‐term legacy of drought and warming on the soil microbial community across five European shrubland ecosystems

We investigated how the legacy of warming and summer drought affected microbial communities in five different replicated long‐term (>10 years) field experiments across Europe (EU‐FP7 INCREASE infrastructure). To focus explicitly on legacy effects (i.e., indirect rather than direct effects of the environmental factors), we measured microbial variables under the same moisture and temperature in a brief screening, and following a pre‐incubation at stable conditions. Specifically, we investigated the size and composition of the soil microbial community (PLFA) alongside measurements of bacterial (leucine incorporation) and fungal (acetate in ergosterol incorporation) growth rates, previously shown to be highly responsive to changes in environmental factors, and microbial respiration. We found no legacy effects on the microbial community size, composition, growth rates, or basal respiration rates at the effect sizes used in our experimental setup (0.6 °C, about 30% precipitation reduction). Our findings support previous reports from single short‐term ecosystem studies thereby providing a clear evidence base to allow long‐term, broad‐scale generalizations to be made. The implication of our study is that warming and summer drought will not result in legacy effects on the microbial community and their processes within the effect sizes here studied. While legacy effects on microbial processes during perturbation cycles, such as drying–rewetting, and on tolerance to drought and warming remain to be studied, our results suggest that any effects on overall ecosystem processes will be rather limited. Thus, the legacies of warming and drought should not be prioritized factors to consider when modeling contemporary rates of biogeochemical processes in soil.     

Leaf chlorophyll content as a proxy for leaf photosynthetic capacity

Improving the accuracy of estimates of forest carbon exchange is a central priority for understanding ecosystem response to increased atmospheric CO₂ levels and improving carbon cycle modelling. However, the spatially continuous parameterization of photosynthetic capacity (Vcmax) at global scales and appropriate temporal intervals within terrestrial biosphere models (TBMs) remains unresolved. This research investigates the use of biochemical parameters for modelling leaf photosynthetic capacity within a deciduous forest. Particular attention is given to the impacts of seasonality on both leaf biophysical variables and physiological processes, and their interdependent relationships. Four deciduous tree species were sampled across three growing seasons (2013–2015), approximately every 10 days for leaf chlorophyll content (Chl_Leaf) and canopy structure. Leaf nitrogen (N_Area) was also measured during 2014. Leaf photosynthesis was measured during 2014–2015 using a Li‐6400 gas‐exchange system, with A‐Ci curves to model Vcmax. Results showed that seasonality and variations between species resulted in weak relationships between Vcmax normalized to 25°C () and N_Area (R² = 0.62, P < 0.001), whereas Chl_Leaf demonstrated a much stronger correlation with (R² = 0.78, P < 0.001). The relationship between Chl_Leaf and N_Area was also weak (R² = 0.47, P < 0.001), possibly due to the dynamic partitioning of nitrogen, between and within photosynthetic and nonphotosynthetic fractions. The spatial and temporal variability of was mapped using Landsat TM/ETM satellite data across the forest site, using physical models to derive Chl_Leaf. TBMs largely treat photosynthetic parameters as either fixed constants or varying according to leaf nitrogen content. This research challenges assumptions that simple N_Area– relationships can reliably be used to constrain photosynthetic capacity in TBMs, even within the same plant functional type. It is suggested that Chl_Leaf provides a more accurate, direct proxy for and is also more easily retrievable from satellite data. These results have important implications for carbon modelling within deciduous ecosystems.     

鳜鱼(Sinipera chuatsi)鱼苗肠道微生态调节的研究

对鳜鱼鱼苗肠道菌进行好氧菌和兼性厌氧菌的分析鉴定 ,发现鳜苗肠道中存在哈夫尼亚菌属和气单胞菌属 ,其中哈夫尼亚菌属量为 4 .8× 10 6cfu/ g ,气单胞菌属量为 2 .4 3× 10 5cfu/ g。哈夫尼亚菌属和气单胞菌属的拮抗实验表明哈夫尼亚菌对气单胞菌的生长有一定的抑制作用。分别用哈夫尼亚菌、气单胞菌作饵料添加剂 ,前者将鱼苗成活率由 18%提高至 33%～ 4 0 % ,后者将鱼苗成活率由 18%降至 2 %～ 4 %。     

蕨类植物的化感作用及其对生物多样性的影响

植物化感作用是植物通过向环境中释放化学物质从而对同种植株和繁殖体或与其他植物之间产生的直接或间接、有益或有害的作用,它影响植物分布、群落形成与演化、作物间作等,与生物多样性保护以及农林和园艺生产实践关系密切,在国际上受到越来越多的关注。但国内这方面的研究起步相对较晚,研究范围有限,对蕨类植物化感作用的报道更少。本文系统介绍了蕨类植物化感作用的研究进展,包括蕨类植物种内的化感作用(即自毒效应)、常见的蕨类植物种间的化感作用(即孢子体对配子体的化感作用和配子体对配子体的化感作用)及蕨类植物对种子植物的化感作用(蕨类植物可通过化感作用与种子植物争夺更多的资源和生长空间)。还介绍了种子植物对蕨类植物的化感作用(主要表现为抑制作用)以及蕨类植物化感作用与动物侵食、微生物侵染的关系,研究发现昆虫侵食能增强或减弱蕨类植物的化感作用,微生物的活动可能增强某些蕨类植物的化感作用。本文从上述不同角度说明蕨类植物化感作用对生物多样性的影响,希望有助于促进我国学者对该领域的深入研究。     

西南干旱河谷植物多样性资源的保护与利用

西南干旱河谷是分布于我国亚热带横断山区的隐域性河谷景观, 其环境受季风气候、岭-谷地形环境和人类开发活动的共同影响。适应于季节性干旱和垂直气候分异, 干旱河谷具有独特的植被和丰富的物种多样性资源。在过去几十年中, 干旱河谷的气候变化以增温为一致特征, 同时经历着广泛的人类活动干扰, 特别是道路建设、水利工程、矿山开发和城镇化驱动的土地利用变化, 造成了普遍的植被破坏、生境退化和生物入侵, 给乡土植物多样性资源和生态系统稳定性带来了严重威胁, 然而至今对干旱河谷生物多样性的保护仍基本属于空白。因此, 建议及时建立干旱河谷的生物多样性保护体系; 因地制宜采取退化植被修复、立体农业规划、特色植物资源利用和风景旅游开发等措施, 以维持干旱河谷生态系统的可持续性; 落实生态文明建设的相关政策, 以保障西南生态屏障的生态安全和生态服务能力。     

互花米草黄酮含量分析及其生态学意义

互花米草原产于北美洲大西洋沿岸和墨西哥海湾,经引种和其他原因,已扩散到包括中国在内的多个国家和地区,并对被入侵地生态系统的结构和功能均造成了显著影响。有关该物种的入侵机制和控制策略是当前入侵生态学研究领域的热点。互花米草生物质材料中富含黄酮类物质,与该物种向海扩张的能力可能存在一定联系。鉴于黄酮广泛的应用价值,能否借助黄酮成分的开发带动生物质的收割,以达到有效控制该物种的目的,也是当前研究者所关注的问题。以芦丁为标准参照物,NaNO2-Al（ NO3）3法比较温室互花米草不同器官中总黄酮含量的差异,分析盐城滩涂互花米草越冬芽黄酮含量与所在地理位置之间的关系,采用L9（34）正交试验对干储互花米草叶总黄酮的提取工艺进行优化。互花米草叶片中黄酮类物质远高于根、根状茎、茎、叶鞘、颖稃及种子。盐城滩涂上互花米草越冬芽的黄酮含量随着由陆向海方向基本呈升高趋势。互花米草总黄酮最佳提取工艺为料液比1∶30,乙醇浓度70％,水浴温度80℃,水浴时间2h。互花米草植物材料中,尤其在叶部,黄酮含量十分丰富。该黄酮物质与互花米草在海岸带盐沼生态系统中的适应和向海扩张也存在正相关关系,可作为探索互花米草入侵机制的一个方向。利用本研究中所得优化提取工艺可从互花米草干储生物质中获得稳定的黄酮来源。配合黄酮经济成分的开发而推动生物质材料的收割利用,将成为互花米草生态控制的一项潜在策略。