Rapid positive response of young trees growth to warming reverses nitrogen loss from subtropical soil

Author:

Lyu Maokui12ORCID,Chen Shidong12,Zhang Qiufang12ORCID,Yang Zhijie12,Xie Jinsheng12,Wang Chao3,Wang Xiaohong12ORCID,Liu Xiaofei12,Xiong Decheng12ORCID,Xu Chao12,Lin Weisheng12,Chen Guangshui12,Chen Yuehmin12,Yang Yusheng12

Affiliation:

1. Key Laboratory for Subtropical Mountain Ecology (Ministry of Science and Technology and Fujian Province Funded) School of Geographical Science, Fujian Normal University Fuzhou China

2. Sanming Forest Ecosystem National Observation and Research Station Sanming China

3. CAS Key Laboratory of Forest Ecology and Management Institute of Applied Ecology, Chinese Academy of Sciences Shenyang China

Abstract

Abstract Global warming is widely expected to alter nitrogen (N) cycling in terrestrial ecosystems by accelerating N transformations in soils. However, it is unclear how warming will affect plant–soil N cycling in subtropical ecosystems. Here, we measured the N transformations including net ammoniation, nitrification, nitrous oxide emissions and nitrate in soil solution throughout the plant–soil continuum with 2 years of experimental soil warming (+5°C) in a young subtropical Chinese fir mesocosm. Seasonal variations of soil and plant (foliage and root) N concentrations and isotopes (δ15N), foliar water use efficiency and arbuscular mycorrhizal colonization rate were measured. Soil warming significantly increased net ammonization and nitrification of the soil, together with the transient positive response observed in inorganic N of the soil. Warming increased nitrate N fluxes in soil solution and nitrous oxide emissions in the first year but not in the second year, suggesting N losses through leaching and gaseous in the initial period of warming. Warming primarily induced enrichment of 15N in foliage relative to the soil, which was attributed to the trade‐offs of persistent increases in plant N uptake caused by enhanced tree growth and a decrease in N losses with continuous warming. Furthermore, young trees' growth and N uptake capacity can rapidly acclimate to climate warming as a result of warming‐induced increases in arbuscular mycorrhizal colonization and foliar water use efficiency. Our findings highlight that warming accelerates the plant–soil N cycle and promotes young trees' growth and N uptake, which in turn reduces soil N lost from this subtropical ecosystem. Therefore, our study suggests that the competition for N between plants and microbes governs whether subtropical forests are opened or closed N cycle systems under climate warming. We predict that subtropical young forests can still maintain their high productivity because young trees can maintain their N uptake capacity and adequate soil N supply in facing future climate warming. Read the free Plain Language Summary for this article on the Journal blog.

Funder

National Natural Science Foundation of China

Publisher

Wiley

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