Key Laboratory of Ecosystem Network Observation and Modeling, Institute of Geographic Sciences and Natural Resources Research, Chinese Academy of Sciences, Beijing 100101, China; College of Resources and Environment, University of Chinese Academy of Sciences, Beijing 100049, China.
Faculty of Natural Resources Management, Lakehead University, Thunder Bay, Ontario, Canada.
Sci Total Environ. 2022 Aug 20;835:155418. doi: 10.1016/j.scitotenv.2022.155418. Epub 2022 Apr 25.
Biodiversity and productivity that highly determine ecosystem services are varying largely under global change. However, the climate sensitivity of them and their relationship are not well understood, especially in the context of increasing nitrogen (N) deposition. Here, based on a six-year N manipulation experiment in an alpine meadow, we quantified interannual climate sensitivity of species richness (SR) and above-ground net primary productivity (ANPP) as well as SR-ANPP relationship as affected by six N addition rate (N) gradients. We found that interannual variations in ANPP and SR were mainly driven by temperature instead of precipitation. In the plots without N addition, higher temperature substantially increased ANPP but reduced SR across years, thus resulting in a negative SR-ANPP relationship. However, the negative and positive responses of SR and ANPP to temperature increased and declined significantly with increasing N, respectively, leading to a shift of the negative relationship between SR and ANPP into a positive one under high N. Moreover, the adverse influence of drought on SR and ANPP would be aggravated by N fertilization, as indicated by the increased positive effect of precipitation on them under N enrichment. Our findings indicate that climate sensitivity of productivity and biodiversity may be misestimated if the impact of N deposition is not considered, and the importance of biodiversity to maintain productivity would enhance as N deposition increases. This study provides a new insight to explain variation of biodiversity-productivity relationship along with environmental changes.
生物多样性和生产力对生态系统服务有重要影响,它们在全球变化下变化很大。然而,它们对气候的敏感性及其关系还没有得到很好的理解,特别是在氮(N)沉积增加的情况下。在这里,我们基于一个为期六年的高山草甸 N 处理实验,量化了物种丰富度(SR)和地上净初级生产力(ANPP)的年际气候敏感性以及它们受六种 N 添加率(N)梯度影响的关系。我们发现,ANPP 和 SR 的年际变化主要受温度驱动,而不是降水。在没有 N 添加的样地中,较高的温度显著增加了 ANPP,但降低了多年的 SR,从而导致 SR-ANPP 关系呈负相关。然而,随着 N 的增加,SR 和 ANPP 对温度的负响应和正响应分别显著增加和下降,导致在高 N 条件下,SR 和 ANPP 之间的负相关关系转变为正相关关系。此外,N 施肥会加剧干旱对 SR 和 ANPP 的不利影响,这表现为在 N 富集下降水对它们的正效应增加。我们的研究结果表明,如果不考虑 N 沉积的影响,生产力和生物多样性的气候敏感性可能会被高估,并且随着 N 沉积的增加,生物多样性对维持生产力的重要性将会增强。这项研究提供了一个新的视角来解释生物多样性-生产力关系随环境变化的变化。
