Resin‐coated urea effectively simulates the chronic dynamics of natural nitrogen deposition

Resin‐coated urea effectively simulates the chronic dynamics of natural nitrogen deposition

Abstract Atmospheric nitrogen (N) deposition has more than tripled globally since the Industrial Revolution. Experiments usually simulate N deposition using fast‐release N fertilizers applied once or several times a year. However, these pulses differ from the continuous N supply of natural depositio...

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Bibliographic Details
Main Authors: Yi Zhao, Yuguang Ke, Honghui Wu, Chong Xu, Xiwen Li, Yann Hautier, Elizabeth T. Borer, Qiang Yu
Format: Article
Language:English
Published: Wiley 2025-07-01
Series:Methods in Ecology and Evolution
Subjects:
biodiversity
coated fertilizer
ecosystem function
ecosystem processes
global change
N deposition
Online Access:https://doi.org/10.1111/2041-210X.70061
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Summary:Abstract Atmospheric nitrogen (N) deposition has more than tripled globally since the Industrial Revolution. Experiments usually simulate N deposition using fast‐release N fertilizers applied once or several times a year. However, these pulses differ from the continuous N supply of natural deposition, which may lead to different outcomes. There is an urgent need for methodologies that more accurately replicate continuous N deposition to better understand its causal impacts on future biological outcomes. We developed a resin‐coated slow‐release urea to stimulate the continuous N deposition dynamics in semiarid grasslands. Three urea ball sizes with varying resin coating thicknesses were designed to achieve year‐long release. We then compared the N release rate of the coated fertilizer to rate of natural N deposition to assess its effectiveness in replicating the temporal pattern of N deposition. Our results showed that under the semiarid conditions of our site, the resin‐coated urea with a 0.5 mm coating on 4 mm diameter balls released urea continuously for approximately 12 months. The temporal pattern of N release rate of the fertilizer was very similar to local atmospheric N deposition. There was a strong positive relationship between N release rates and N deposition (R2 = 0.80), with both exhibiting simultaneous peaks and valleys. Our results indicate that resin‐coated urea with a pellet size and coating thickness determined by local site conditions can effectively simulate the temporal dynamics of N deposition. Coated urea provides a far more effective approach for experimentally simulating future impacts of elevated N deposition on ecosystem function and processes compared to fast‐release fertilizers.
ISSN:2041-210X

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