荒漠短命植物地上和地下生产力对极端干旱和降水的响应

在古尔班通古特沙漠南缘沙垄4个坡位和坡向,设置减少65%和增加65%生长季降水量以模拟极端干旱和极端降水事件,研究极端干旱和极端降水事件对沙垄不同坡位和坡向短命植物层片生产力的影响。结果表明: 极端干旱使地上净初级生产力和地下净初级生产力分别显著降低48.8%和13.7%,极端降水使地上净初级生产力和地下净初级生产力分别显著增加37.9%和23.2%。地上净初级生产力对极端干旱和极端降水的敏感性(0.26和0.21 g·m^-2·mm^-1)显著强于地下净初级生产力的敏感性(0.02和0.03 g·m^-2·mm^-1)。沙垄东坡地上净初级生产力(24.22 g·m^-2)和地下净初级生产力(5.77 g·m^-2)与西坡相比显著增大29.7%和71.7%,而地上净初级生产力和地下净初级生产力对降水变化的敏感性在不同坡位和坡向之间差异不显著。     

1980—2013年中国陆地生态系统总初级生产力对干旱的响应特征

干旱事件通过影响陆地生态系统的组成、结构和功能显著改变整个陆地生态系统碳循环。陆地生态系统总初级生产力(GPP)是全球陆地碳通量中最大的组成部分,反映了陆地生态系统的生产力水平。本研究利用基于过程模型模拟的GPP数据(DLM GPP)、基于通量观测升尺度的GPP数据(FLUXCOM GPP)和标准化降水蒸散指数(SPEI),量化分析了1980—2013年中国陆地生态系统GPP和干旱的时空格局,讨论了不同时间尺度上GPP对干旱的响应特征。结果表明:1980—2013年,两种不同GPP数据在中国地区呈现的时间变化趋势的空间分布格局较为一致,上升趋势主要分布在西南地区,下降趋势主要分布在东北大部分地区;中国干旱面积的长期时间变化趋势略有下降,其中干旱化趋势主要位于秦岭淮河以南地区,而西北内陆地区则呈现明显的湿润化趋势;时间尺度上,GPP与SPEI年际变化格局基本吻合,1986、1997、2001和2011年等干旱年份的GPP显著降低;空间尺度上,北方大部分地区的GPP与SPEI呈正相关,南方大部分地区呈负相关,干旱对GPP的影响在半干旱地区表现更加明显; GPP对干旱的响应格局与选取干旱指数...     

陆地生态系统过程对气候变暖的响应与适应

陆地生态系统包含一系列时空连续、尺度多元且互相联系的生态学过程。由于大部分生态学过程都受到温度调控, 因此气候变暖会对全球陆地生态系统产生深远的影响。近年来, 全球变化生态学的基本科学问题之一是陆地生态系统的关键过程如何响应与适应全球气候变暖。围绕该问题, 该文梳理了近年来的研究进展, 重点关注植物生理生态过程、物候期、群落动态、生产力及其分配、凋落物与土壤有机质分解、养分循环等过程对温度升高的响应与适应机理。通过定量分析近20年来发表于主流期刊的相关论文, 展望了该领域的前沿方向, 包括物种性状对生态系统过程的预测能力, 生物地球化学循环的耦合过程, 极端高温与低温事件的响应与适应机理, 不对称气候变暖的影响机理和基于过程的生态系统模拟预测等。基于这些研究进展, 该文建议进一步研究陆地生态系统如何适应气候变暖, 更多关注我国的特色生态系统类型, 并整合实验、观测或模型等研究手段开展跨尺度的合作研究。     

中国西南部地区植被对极端气候事件的响应

在全球气候变化背景下, 极端气候事件频发。中国西南部地区植被对于气候变化及极端气候事件的响应较为敏感。为探究西南部地区植被对极端气候事件的响应程度, 该文采用Pettitt检验、趋势分析法对数据进行分析, 并对数据进行去趋势处理, 分析去趋势前后极端气候指数与归一化植被指数(NDVI)的相关关系。结果表明: (1) 1982-2015年西南部地区植被NDVI呈现显著上升的趋势, NDVI在1994年发生突变, 突变前上升不显著, 突变后呈现显著上升的趋势; (2)去趋势前, 1982-2015年间, 极端降水指数与NDVI显著相关的仅有1日最大降水量, 其与NDVI显著正相关; 除气温日较差外, 其他极端温度指数均与NDVI显著相关。1994-2015年间, 1日最大降水量与NDVI显著正相关, 降水日数与NDVI显著负相关; 在极端温度指数中, 日最低气温最大值、暖昼日数、夏季日数、生长季长度和气温日较差与NDVI显著正相关, 冷昼日数、冰冻日数、冷夜日数和霜冻日数与NDVI显著负相关。1982-2015年间NDVI对年平均气温的响应最强, 而在1994-2015年间NDVI对夏季日数和气温日较差的响应强于对年平均气温的响应。(3)去趋势后, 极端降水指数与NDVI的相关性在两个时段都不显著; 而日最高气温最大值、暖昼日数、夏季日数和气温日较差在这两个时段与NDVI显著正相关, 但其与NDVI的相关系数都在1994-2015年间更高。气温日较差在两个时段与NDVI的相关系数都最高。只在1982-2015年冷昼日数与NDVI显著负相关。     

气候变化对叶尔羌河流域极端水文事件的影响

通过选取叶尔羌河流域 4 个典型气象、水文观测站点的月值数据, 对比分析了气候变化背景下叶尔羌河流域气温、降水及径流的演变特征, 并探究了其对极端水文事件响应。结果表明: (1)气候变化中, 近 55 a 叶尔羌河流域气候变化整体呈增暖增湿趋势, 以 1998 年变化最为显著, 且 4 个典型观测站中库鲁克栏杆站气温及降水变化率最大(0.24 ℃·10a–1, 7.41 mm·10 a–1); (2)径流变化整体呈线性增加趋势且年内变化显著, 其中叶尔羌河及提孜那普河年内径流量最大值分布集中于 7 月和 8 月; (3)近 55 a 叶尔羌河流域极端水文事件呈显著增加趋势, 且以 6 月径流变化最为显著, 降水增加及冰川加速消融是流域极端水文事件频发的主导因子。因此, 加强水文事件对气候变化的应对措施和洪水灾害的影响评估, 对提高叶尔羌河流域水资源的利用效率, 减少其气候变化的危害具有重要意义。     

长江三角洲气候极端事件的预测及其与埃尔尼诺和南方涛动（ENSO）…

通过研究长江三角洲近５００年来的气候历史记录,揭示了这种气候极端事件出现的规律,模式,及其与全球气候变迁的关系,在过去５００年中（自公元１５００年以来）,共出现了１６个区域性气候极端事件,所有这些事件都与所报道的埃尔尼诺和南方涛动（ＥＮＳＯ）事件有关,研究表明,本区降地雨量大的年际变化都出现在ＥＮＳＯ事件之中或之后,因此长江三角洲这种受人影响日益增强的系统管理,必须考虑到这种主要气候变化的周期,以     

淮河流域暖季极端高温干旱复合事件的演变特征及其与气候和植被的关系

使用淮河流域1981年至2020年的149个气象站点的气温和相对湿度数据,分析了流域暖季极端高温干旱复合事件(Compound Drought and Heat Events,CDHEs)的时空演变特征,并通过趋势分析和相关分析法探讨了CDHEs与气候和植被的关系。结果表明:①CDHEs的发生日数在年代际尺度上呈现明显的增加趋势,并且范围扩大,频发区逐渐向淮河流域中西部移动;②在年际尺度上,CDHEs随时间序列呈显著的波动上升趋势,空间分布上以西北部为中心向四周递减。连续CDHEs事件呈年际变化,最大2至4天的连续事件存在波动,2019年达到高峰,并且在流域内零散或成片出现;③在月际尺度上,CDHEs的发生日数在6月最多,其次是5月、7月、9月和8月。淮河流域入汛前的旱情和入汛后的旱涝急转都容易导致CDHEs发生,而且随着月际变化向南移动;④CDHEs对水热条件和大气环流具有特别的敏感性。在850hPa反气旋和500hPa显著高压异常的控制下,高温、低湿、高蒸发和降水少的气候背景有利于淮河地区CDHEs的形成,尤其是在淮河中西部地区。因此,CDHEs的发生与气候变化密切相关;⑤CDHEs与植被生长也存在显著关系。CDHEs与GPP呈显著的负相关,而与NDVI呈显著的正相关,显著地区的土地类型以耕地和城乡、工矿、居民用地为主。GPP和NDVI的不同步可能是因为多种因素的非线性相互作用,而不仅仅是单一因素的影响。此外,对于GPP和NDVI来说,土壤含水量至关重要。总之,本文对淮河流域CDHEs的时空分布特征进行了深入研究,并探讨了其与气候和植被的关系。研究结果可以为该地区的气象灾害防御和生态环境保护提供科学依据和参考。     

我国极端降水变化趋势及其对城市排水压力的影响

全球气候变化对水循环具有重要影响,其中极端降水的变化,对城市排水系统产生巨大冲击,造成城市内涝、交通瘫痪及生命财产损失等问题。为了揭示我国极端降水变化的趋势和区域特征,及其对城市排水系统的压力程度,使用中国气象数据中心1951—2014年全国917个站点的逐日降水量,计算得到我国极端降水及其变化趋势的空间分布特征。并以我国289个主要地级城市为研究对象,构建了气候变化情景下的城市排水压力评估方法,预测并展望了不同时段和不同代表性浓度路径(RCPs)情景下,未来城市的排水压力情况。结果表明,我国极端降水整体上正随着全球气候变化而增加,全国年最大降水量变化速度的平均值为0.06mm/a,但并不是所有区域都具有一致性,具体表现为南部极端降水增加而北部缓解的规律。我国排水压力大的城市主要分布在南部和东北地区,城市排水基础设施完善的东部和极端降水量比较小的西部地区城市排水压力比较低,华北地区极端降水的随机性大,历史上出现的最大降水显著高于该地区常见大雨,也属于内涝风险比较大的区域。随着气候变化的影响,我国未来城市排水压力整体上升,城市未来短期排水压力相对于现有水平总体上升2.9%,具体75个城市的排水压力有所增加明显。且低应对的RCP8.5情景显著高于高应对的RCP2.6情景,这说明减缓气候变化的工作对降低我国城市内涝风险有比较大的积极意义。我国城市排水压力的变化也具有区域性,华北地区极端降水呈现减少的趋势,南部地区极端降水呈现增加趋势,加重了该地区原本就很高的城市内涝风险,需要政府采取积极措施提出有针对性的方案和考虑了气候变化的前瞻性城市排水规划,以降低城市排水压力,尽量减少城市内涝造成的经济损失。     

东北地区近50年来极端降水和干燥事件时空演变特征

利用东北地区93个国家常规气象观测站1951~2002年逐日降水资料,分析了东北地区的暴雨、严重干燥事件等极端降水事件的时空演变特征,从极端降水事件发生频率和强度变化的角度解释旱涝灾害加剧的原因。结果表明,近52年来,小雨事件发生频次显著减少;暴雨发生频次变化不大,但强度增强;严重干燥事件显著增加;严重湿润事件显著下降。因此,在东北地区降水总量具有减少趋势的背景下,降水事件还有向极端化发展的倾向,降水分布变得更不均匀,从而可能引起更多、更强的旱涝灾害,尤其是旱灾,从而对东北地区的生态环境,尤其是农业生产带来不利的影响,这应引起重视。     

1960—2014年松嫩草地极端气候事件的时空变化

基于1960—2014年松嫩草地13个气象站点的日值记录数据,计算与区域水旱寒热灾害、植被生长发育密切相关的14个极端气候指数;利用线性趋势法、间断趋势分析法、Mann-Kendall检验、Sen斜率估计和滑动t检验等方法,分析松嫩草地极端气候事件的发生趋势与时空格局.结果表明: 表征极端高温指数的夏日日数、暖昼日数、暖夜日数、暖持续指数均呈显著上升趋势,表征低温指数的霜日日数、冷昼日数、冷夜日数、冷持续指数均呈明显下降趋势,区域变暖趋势显著;区域极端低温的增幅大于极端高温的增幅,夜间增温幅度大于白昼;1970—2009年区域气候变暖趋势较为明显,各指数突变也集中发生在这一时期;表征极端降水的各指数变化趋势不显著,普通日降水强度和持续干燥指数呈下降趋势,5日最大降水量、强降水量、年湿期降水总量和持续湿润指数呈微弱上升趋势,表明区域气候呈微弱的暖湿化特征;松嫩草地南部和北部地区是对气候变暖响应最显著的区域;对极端降水指数而言,各指数南北分异特征明显,区域北部以变湿为主要特征,而南部则以变干为主要特征,尤其是区域西南部的干旱风险较高.     

Effects of extreme drought on terrestrial ecosystems: review and prospects

作为地球表层重要的组成部分, 陆地生态系统是人类生存和发展的重要场所。进入21世纪以来, 气候变化导致干旱事件发生的强度、频度和持续时间显著增加, 对陆地生态系统带来深远的影响, 严重制约甚至威胁人类社会的可持续发展。因此, 开展极端干旱对陆地生态系统影响的研究并评估其生态风险效应, 是当前全球变化领域研究的重点问题。该文从植物生理生态过程、生物地球化学循环、生物多样性以及生态系统结构和功能4个方面综述了极端干旱对陆地生态系统的影响, 并对当前的研究热点进行探讨, 深度剖析当前研究中存在的难点问题和未来可能的发展方向, 以期为未来开展干旱对陆地生态系统影响的观测与预测研究提供参考, 为在未来干旱影响下加强陆地生态系统风险评估和管理提供新思路。     

Sensitivity of three grassland communities to simulated extreme temperature and rainfall events

Three grassland communities in New Zealand with differing climates and proportions of C3 and C4 species were subjected to one‐off extreme heating (eight hours at 52.5°C) and rainfall (the equivalent of 100 mm) events. A novel experimental technique using portable computer‐controlled chambers simulated the extreme heating events. The productive, moist C3/C4 community was the most sensitive to the extreme events in terms of short‐term community composition compared with a dry C3/C4 community or an exclusively C3 community. An extreme heating event caused the greatest change to plant community species abundance by favouring the expansion of C4 species relative to C3 species, shifting C4 species abundance from 43% up to 84% at the productive, moist site. This was observed both in the presence and absence of added water. In the absence of C4 species, heating reduced community productivity by over 60%. The short‐term shifts in the abundance of C3 and C4 species in response to the single extreme climatic events did not have persistent effects on community structure or on soil nitrogen one year later. There was no consistent relationship between diversity and stability of biomass production of these plant communities, and species functional identity was the most effective explanation for the observed shifts in biomass production. The presence of C4 species resulted in an increased stability of productivity after extreme climatic events, but resulted in greater overall shifts in community composition. The presence of C4 species may buffer grassland community productivity against an increased frequency of extreme heating events associated with future global climate change.     

Impacts of extreme climatic events on competition during grassland invasions

Phytometers of five C3 and five C4 species were transplanted into three different grasslands to study the effects of extreme climatic events on community invasibility and competition. Single extreme heating (eight hours at 52.5 °C) and rainfall (the equivalent of 100 mm) events in factorial combinations were superimposed on the grassland communities. A novel technique involving portable computer‐controlled chambers was used to create the heating events. In order to generate predictions of response to the extreme climatic events, the 10 phytometer species were categorized on the basis of 12 key plant functional traits. Using principal component analysis, two functional types (FTs) were identified as most likely to be advantaged (FT1, fast‐growing C4 annuals) and disadvantaged (FT2, slower‐growing C3 perennials) by an extreme climatic event. Competition between the resident vegetation and FT1 plus other C4 phytometers was consistently more intense within the exclusively C3 community compared to the dry C3/C4 community or moist C3/C4 community. The single extreme heating event had the greatest impact on competition, lowering the intensity of competition between the phytometers and resident vegetation. Our results indicate that competition is highly important in limiting the invasion of C3 grasslands by C4 species. The FT1 and FT2 responses confirmed predictions based on plant functional traits, whether growing as phytometers or as part of the resident vegetation. Future increases in climatic variability and the incidence of extreme climatic events are expected to suppress C3 competitive dominance and promote invasion of C4 species, in particular, the FT1 species.     

Contingent productivity responses to more extreme rainfall regimes across a grassland biome

Climate models predict, and empirical evidence confirms, that more extreme precipitation regimes are occurring in tandem with warmer atmospheric temperatures. These more extreme rainfall patterns are characterized by increased event size separated by longer within season drought periods and represent novel climatic conditions whose consequences for different ecosystem types are largely unknown. Here, we present results from an experiment in which more extreme rainfall patterns were imposed in three native grassland sites in the Central Plains Region of North America, USA. Along this 600 km precipitation–productivity gradient, there was strong sensitivity of temperate grasslands to more extreme growing season rainfall regimes, with responses of aboveground net primary productivity (ANPP) contingent on mean soil water levels for different grassland types. At the mesic end of the gradient (tallgrass prairie), longer dry intervals between events led to extended periods of below-average soil water content, increased plant water stress and reduced ANPP by 18%. The opposite response occurred at the dry end (semiarid steppe), where a shift to fewer, but larger, events increased periods of above-average soil water content, reduced seasonal plant water stress and resulted in a 30% increase in ANPP. At an intermediate mixed grass prairie site with high plant species richness, ANPP was most sensitive to more extreme rainfall regimes (70% increase). These results highlight the inherent complexity in predicting how terrestrial ecosystems will respond to forecast novel climate conditions as well as the difficulties in extending inferences from single site experiments across biomes. Even with no change in annual precipitation amount, ANPP responses in a relatively uniform physiographic region differed in both magnitude and direction in response to within season changes in rainfall event size/frequency.     

Changes in grassland ecosystem function due to extreme rainfall events: implications for responses to climate change

Climate change is causing measurable changes in rainfall patterns, and will likely cause increases in extreme rainfall events, with uncertain implications for key processes in ecosystem function and carbon cycling. We examined how variation in rainfall total quantity (Q), the interval between rainfall events (I), and individual event size (S_E) affected soil water content (SWC) and three aspects of ecosystem function: leaf photosynthetic carbon gain (), aboveground net primary productivity (ANPP), and soil respiration (). We utilized rainout shelter‐covered mesocosms (2.6 m³) containing assemblages of tallgrass prairie grasses and forbs. These were hand watered with 16 I×Q treatment combinations, using event sizes from 4 to 53 mm. Increasing Q by 250% (400–1000 mm yr^?1) increased mean soil moisture and all three processes as expected, but only by 20–55% (P≤0.004), suggesting diminishing returns in ecosystem function as Q increased. Increasing I (from 3 to 15 days between rainfall inputs) caused both positive () and negative () changes in ecosystem processes (20–70%, P≤0.01), within and across levels of Q, indicating that I strongly influenced the effects of Q, and shifted the system towards increased net carbon uptake. Variation in S_E at shorter I produced greater response in soil moisture and ecosystem processes than did variation in S_E at longer I, suggesting greater stability in ecosystem function at longer I and a priming effect at shorter I. Significant differences in ANPP and between treatments differing in I and Q but sharing the same S_E showed that the prevailing pattern of rainfall influenced the responses to a given event size. Grassland ecosystem responses to extreme rainfall patterns expected with climate change are, therefore, likely to be variable, depending on how I, Q, and S_E combine, but will likely result in changes in ecosystem carbon cycling.     

Spatial patterns and drivers of root turnover in grassland ecosystems in China

根系周转是陆地生态系统物质循环的关键指标, 也是陆地生态系统净初级生产力及碳固持潜力估算的核心参数。然而, 由于地下净初级生产力数据获取困难, 区域和全球尺度上的相关研究十分有限, 尤其是分布广泛的中国草地, 区域尺度上的整合研究几乎为空白。基于样地实测数据、已发表文献和在线数据库数据, 对中国草地5种植被类型、共计154个草地生态系统根系周转的空间格局进行整合分析, 并结合气象和土壤数据, 揭示了草地生态系统根系周转的关键驱动因子。研究发现: (1)根系周转速率随纬度升高而降低, 低纬度温暖地区根系周转更快; (2)气候因子(年平均气温、年降水量)和土壤理化性质(砾石含量、容重、pH值)共同影响根系周转, 对周转变异性的解释度为44%, 其中气候因子的相对贡献率为57%, 土壤理化性质的相对贡献率为43%; (3)中国草地根系周转的格局和驱动因子与全球尺度的研究结果不尽相同。该研究对根系周转的驱动因子提出了新的观点和证据, 为全球尺度上的整合研究提供了关键数据。     

New perspectives on forest soil carbon and nitrogen cycling processes: Roles of arbuscular mycorrhizal versus ectomycorrhizal tree species

Nearly all tree species develop symbiotic relationships with either arbuscular mycorrhizal (AM) or ectomycorrhizal (EM) fungi to acquire nutrients from soils, and hence influence soil carbon (C) and nitrogen (N) cycles in terrestrial ecosystems. It is crucial to understand the differences in soil C and N cycles between AM and EM forests and the underlying mechanisms. In this review, we first compared the differences in the soil C and N cycles between AM and EM forests, and synthesized the underlying mechanisms from perspectives of the inputs, stabilization, and outputs of soil C and N in forest ecosystems. We also compared the responses of soil C and N cycles between AM and EM forests to global changes. In this field, one major research priority is comparing the structure and function (including the soil C and N cycles) between AM and EM forest ecosystems to provide theoretical basis and solid data for improving forest productivity and ecosystem services. The second research focus is deepening the understanding of the effects of interactions between aboveground litter and belowground mycorrhiza and free-living microbes on soil C and N cycles to reveal the potential underlying mechanisms in forests with different mycorrhizal symbioses. Third, the research methodology and new techniques need refining and applying to explicitly focus on scaling up the fine-scale measurements to better expound and predict the C and N cycles in forest ecosystems. Finally, more studies on the stability of soil organic matter among different mycorrhizal forests are needed to precisely assess responses of the structure and function of forest ecosystems to global changes.     

Responses of aquatic macrophyte cover and productivity to flooding variability on the Amazon floodplain

Macrophyte net primary productivity (NPP) is a significant but understudied component of the carbon budget in large Amazonian floodplains. Annual NPP is determined by the interaction between stem elongation (vertical growth) and plant cover changes (horizontal expansion), each affected differently by flood duration and amplitude. Therefore, hydrological changes as predicted for the Amazon basin could result in significant changes in annual macrophyte NPP. This study investigates the responses of macrophyte horizontal expansion and vertical growth to flooding variability, and its possible effects on the contribution of macrophytes to the carbon budget of Amazonian floodplains. Monthly macrophyte cover was estimated using satellite imagery for the 2003–2004 and 2004–2005 hydrological years, and biomass was measured in situ between 2003 and 2004. Regression models between macrophyte variables and river‐stage data were used to build a semiempirical model of macrophyte NPP as a function of water level. Historical river‐stage records (1970–2011) were used to simulate variations in NPP, as a function of annual flooding. Vertical growth varied by a factor of ca. 2 over the simulated years, whereas minimum and maximum annual cover varied by ca. 3.5 and 1.5, respectively. Results suggest that these processes act in opposite directions to determine macrophyte NPP, with larger sensitivity to changes in vertical growth, and thus maximum flooding levels. Years with uncommonly large flooding amplitude resulted in the highest NPP values, as both horizontal expansion and vertical growth were enhanced under these conditions. Over the simulated period, annual NPP varied by ca. 1.5 (1.06–1.63 TgC yr^?1). A small increasing trend in flooding amplitude, and by extension NPP, was observed for the studied period. Variability in growth rates caused by local biotic and abiotic factors, and the lack of knowledge on macrophyte physiological responses to extreme hydrological conditions remain the major sources of uncertainty.     

Research progress on the effects of grazing on grassland ecosystem

全球草地占据30%左右的陆地面积, 在全球气候变化、碳氮及养分循环、保持水土、调节畜牧业生产等方面具有重要的作用。目前草地的主要利用方式之一就是放牧, 不同的牲畜种类、放牧强度、年限、历史和制度等, 会影响草地植物群落、生物多样性及土壤微生物, 进而影响草地生态系统结构、功能和过程。该文围绕放牧对草地生态系统结构、功能和过程的影响, 1)回顾了20世纪50年代到现在各个历史阶段放牧对草地生态系统影响的研究; 2)利用文献计量分析的方法, 剖析了放牧对草地影响研究的热点内容、重要区域和关键词等; 3)阐明了放牧对草地植物生长、群落特征、碳氮及养分循环、生产力及土壤质量等的各方面影响的研究进展及国内相关研究的优势及存在的主要问题和不足; 4)基于上述分析, 从草地放牧精准管理、经典假说验证、放牧和全球变化研究相结合等方面, 提出未来研究的前沿方向和优先领域。该文在系统总结放牧对草地生态系统影响的研究进展、研究优势及存在问题的基础上, 提出未来的研究应与全球变化相结合, 为我国的草地放牧生态学研究、适应性管理和可持续利用等提供科学基础。     

Response and adaptation of terrestrial ecosystem processes to climate warming

陆地生态系统包含一系列时空连续、尺度多元且互相联系的生态学过程。由于大部分生态学过程都受到温度调控, 因此气候变暖会对全球陆地生态系统产生深远的影响。近年来, 全球变化生态学的基本科学问题之一是陆地生态系统的关键过程如何响应与适应全球气候变暖。围绕该问题, 该文梳理了近年来的研究进展, 重点关注植物生理生态过程、物候期、群落动态、生产力及其分配、凋落物与土壤有机质分解、养分循环等过程对温度升高的响应与适应机理。通过定量分析近20年来发表于主流期刊的相关论文, 展望了该领域的前沿方向, 包括物种性状对生态系统过程的预测能力, 生物地球化学循环的耦合过程, 极端高温与低温事件的响应与适应机理, 不对称气候变暖的影响机理和基于过程的生态系统模拟预测等。基于这些研究进展, 该文建议进一步研究陆地生态系统如何适应气候变暖, 更多关注我国的特色生态系统类型, 并整合实验、观测或模型等研究手段开展跨尺度的合作研究。