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Peter B. Reich; Peter B. Reich;Peter B. Reich
Harvested from ORCID Public Data FilePeter B. Reich in OpenAIRE Benjamin D. Stocker; Benjamin D. Stocker
Harvested from ORCID Public Data FileBenjamin D. Stocker in OpenAIRE César Terrer; +5 AuthorsCésar Terrer
Harvested from ORCID Public Data FileCésar Terrer in OpenAIRE Peter B. Reich; Peter B. Reich;Peter B. Reich
Harvested from ORCID Public Data FilePeter B. Reich in OpenAIRE Benjamin D. Stocker; Benjamin D. Stocker
Harvested from ORCID Public Data FileBenjamin D. Stocker in OpenAIRE César Terrer; César Terrer
Harvested from ORCID Public Data FileCésar Terrer in OpenAIRE Richard P. Phillips; Richard P. Phillips
Harvested from ORCID Public Data FileRichard P. Phillips in OpenAIRE Sara Vicca; Sara Vicca
Harvested from ORCID Public Data FileSara Vicca in OpenAIRE I. Colin Prentice; Adrien C. Finzi; Bruce A. Hungate;I. Colin Prentice
Harvested from ORCID Public Data FileI. Colin Prentice in OpenAIREContents Summary 507 I. Introduction 507 II. The return on investment approach 508 III. CO2 response spectrum 510 IV. Discussion 516 Acknowledgements 518 References 518 SummaryLand ecosystems sequester on average about a quarter of anthropogenic CO2 emissions. It has been proposed that nitrogen (N) availability will exert an increasingly limiting effect on plants’ ability to store additional carbon (C) under rising CO2, but these mechanisms are not well understood. Here, we review findings from elevated CO2 experiments using a plant economics framework, highlighting how ecosystem responses to elevated CO2 may depend on the costs and benefits of plant interactions with mycorrhizal fungi and symbiotic N‐fixing microbes. We found that N‐acquisition efficiency is positively correlated with leaf‐level photosynthetic capacity and plant growth, and negatively with soil C storage. Plants that associate with ectomycorrhizal fungi and N‐fixers may acquire N at a lower cost than plants associated with arbuscular mycorrhizal fungi. However, the additional growth in ectomycorrhizal plants is partly offset by decreases in soil C pools via priming. Collectively, our results indicate that predictive models aimed at quantifying C cycle feedbacks to global change may be improved by treating N as a resource that can be acquired by plants in exchange for energy, with different costs depending on plant interactions with microbial symbionts.
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