陆地生态系统过程对气候变暖的响应与适应

doi:10.17521/cjpe.2019.0323

摘要/Abstract

摘要：

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。

关键词: 气候变暖, 生态过程, 碳循环, 氮循环, 生产力, 极端气候事件

Abstract:

Terrestrial ecosystems are characterized by a series of spatiotemporally continuous, multiple scaled, and mutually connected processes. Since most of these ecological processes are regulated by temperature, climate warming will profoundly impact terrestrial ecosystems at global scale. Recently, how key processes in terrestrial ecosystems respond and/or adapt to climate warming has become a fundamental question in global change ecology. Here, we reviewed the recent research progress related to such question. This review focuses on key ecosystem processes, such as plant ecophysiological processes, phenology, community dynamics, productivity and carbon allocation, decomposition of litter and soil organic carbon, nutrient cycling, and carbon-nitrogen coupling. Based on a literature review, we propose perspectives for future research to tackle fundamental questions, such as the predictability of plant traits on ecosystem processes, coupling between biogeochemical cycles, mechanisms driving ecosystem responses to extreme climate and asymmetric warming, and ecological forecasting with models. We finally suggest more research efforts on warming adaptation rather than response on China’s specific ecosystems, and on the integration of experiments, observations, and models for coordinating studies across scales.

Key words: climate warming, ecosystem processes, carbon cycle, nitrogen cycle, productivity, extreme climate

夏建阳, 鲁芮伶, 朱辰, 崔二乾, 杜莹, 黄昆, 孙宝玉. 陆地生态系统过程对气候变暖的响应与适应. 植物生态学报, 2020, 44(5): 494-514. DOI: 10.17521/cjpe.2019.0323

XIA Jian-Yang, LU Rui-Ling, ZHU Chen, CUI Er-Qian, DU Ying, HUANG Kun, SUN Bao-Yu. Response and adaptation of terrestrial ecosystem processes to climate warming. Chinese Journal of Plant Ecology, 2020, 44(5): 494-514. DOI: 10.17521/cjpe.2019.0323

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链接本文: https://www.plant-ecology.com/CN/10.17521/cjpe.2019.0323

https://www.plant-ecology.com/CN/Y2020/V44/I5/494

图/表 4

图1 气候变暖对陆地生态系统关键过程的影响。①氮矿化过程; ②氮固持过程; ③氮吸收过程; ④反硝化过程; ⑤固氮过程; ⑥氮淋溶与径流过程。绿色虚线方框代表各关键过程, 蓝色方框代表各碳氮储存库, 虚线箭头表示碳氮耦合过程。

Fig. 1 Impact of climate warming on key processes in terrestrial ecosystems. ① N mineralization; ② N immobilization; ③ N uptake; ④ N denitrification; ⑤ N fixation; ⑥ N leaching and running off. GPP, gross primary productivity; NPP, net primary productivity. Green dashed boxes indicate key processes, blue boxes show C and N storage pools, and dashed arrows represent the carbon-nitrogen coupling processes.

图2 生态系统部分关键过程响应气候变暖的证据量、一致性及置信度。证据量是指报道该生态系统过程的研究文献数量, 一致性是指所有文献中支持该响应现象的百分比例。置信度由证据量与一致性的乘积表示。该方法参考了第五次IPCC报告(IPCC, 2013)中的置信度概念, 并沿用了Xia等(2014)一文中的表达方法。本图中涉及的具体发表文献请见附录I。

Fig. 2 Evidence, agreement and thus confidence of key ecosystem processes in response to climate warming. “Evidence” shows the number of studies that report on ecosystem processes. “Agreement” indicates the percentage of evidence supporting the specific warming response. Confidence is the product of “Evidence” and “Agreement” and is based on the confidence concept in the fifth IPCC report (IPCC, 2013). The figure was adapted from Xia et al. (2014). Data was obtained by a comprehensive literature search (Supplement I). ① photosynthetic acclimation; ② photosynthetic overcomepensation; ③ acclimation of plant respiration; ④ acclimation of soil respiration; ⑤ earlier spring phenology; ⑥ delayed autumn phenology; ⑦ changed species composition of plant community; ⑧ enhanced ecosystem productivity; ⑨ faster decomposition of soil organic matter; ⑩ faster soil nutrient mineralization.

图3 4份主流期刊(Science、Nature、PNAS与Global Change Biology (GCB))在2000-2019年间的发表文章数量(A)及其在研究方法(B)与生态学过程(C)方面的分布情况。论文检索结果来源于各期刊网站, 首先采用关键词“warming”进行搜索。然后, 再逐篇筛查是否包含陆地生态系统过程。中国地区的文章即第一作者单位为中国境内的研究机构。

Fig. 3 Publications of four high-impact journals (Science、Nature、PNAS与Global Change Biology (GCB))(2000-2019), including the total number of papers (A) and their distribution in different methods (B) and ecological processes (C). Literature was first searched by the keyword “warming” from the homepage of each journal, then manually screened for whether it includes terrestrial ecosystem processes. The black line for “China” represents the published papers with the first affiliated address located in China.

图4 整合实验、野外调查观测与模型方法研究陆地生态系统响应与适应气候变暖的思路框架。图中的实验与模型的整合参考了Medlyn等(2015)的思路。需要说明的是, 该框架在研究具体的科学问题时需要根据实际情况进行调整。

Fig. 4 Conceptual framework of experiments, field observations, and modeling to study response and adaptation of terrestrial ecosystems to warming. The integration of experiments and models in the figure was adapted from Medlyn et al. (2015). It should be noted that this framework needs to be adjusted according to the specific scientific question.

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