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Inhibition of Elevated Atmospheric Carbon Dioxide to Soil Gross Nitrogen Mineralization Aggravated by Warming in an Agroecosystem.

Xiaoshun TuJing WangXiaoyu LiuAhmed S ElrysYi ChengJinbo ZhangZu-Cong CaiChristoph Müller
Published in: Environmental science & technology (2022)
The response of soil gross nitrogen (N) cycling to elevated carbon dioxide (CO 2 ) concentration and temperature has been extensively studied in natural and semi-natural ecosystems. However, how these factors and their interaction affect soil gross N dynamics in agroecosystems, strongly disturbed by human activity, remains largely unknown. Here, a 15 N tracer study under aerobic incubation was conducted to quantify soil gross N transformation rates in a paddy field exposed to elevated CO 2 and/or temperature for 9 years in a warming and free air CO 2 enrichment experiment. Results show that long-term exposure to elevated CO 2 significantly inhibited or tended to inhibit gross N mineralization at elevated and ambient temperatures, respectively. The inhibition of soil gross N mineralization by elevating CO 2 was aggravated by warming in this paddy field. The inhibition of gross N mineralization under elevated CO 2 could be due to decreased soil pH. Long-term exposure to elevated CO 2 also significantly reduced gross autotrophic nitrification at ambient temperature, probably due to decreased soil pH and gross N mineralization. In contrast, none of the gross N transformation rates were affected by long-term exposure to warming alone. Our study provides strong evidence that long-term dual exposure to elevated CO 2 and temperature has a greater negative effect on gross N mineralization rate than the single exposure, potentially resulting in progressive N limitation in this agroecosystem and ultimately increasing demand for N fertilizer.
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