Nitrogen fertilization-induced acidity and suitability of δ13C to study the dynamics of soil inorganic carbon in agroecosystems

authored by

Mostafa Abdollahpour, Dennis Hollemann, Leopold Sauheitl, Georg Guggenberger, Kazem Zamanian

Abstract

Neutralization of soil inorganic carbon (SIC), i.e., dissolution of carbonate minerals caused by N fertilization-induced acidity, is an ongoing reaction in agroecosystems that leads to significant contribution of SIC to soil CO

₂ emission. Analyzing δ

¹³C natural abundance of the emitted CO

₂ is commonly used to quantify the contribution of SIC in total CO

₂ emission. However, carbonates recrystallization in isotopic equilibrium with soil respiration can lead to miscalculation, where despite detecting δ

¹³C signal from carbonates in the emitted CO

₂, the SIC stock may not necessarily change. We tested the effects of ammonium sulfate, urea, chicken manure, liquid pig manure and no fertilization (i.e. control) on soil carbonates neutralization and the contribution of SIC in total CO

₂ emission over a 21 day incubation experiment. The alkali trap method was used to measure the total CO

₂ emission and the isotopic composition of carbon (C) in the emitted CO

₂ from the soil. Liquid pig manure followed by ammonium sulfate apparently led to the highest cumulative SIC-originated CO

₂ emissions, while chicken manure and urea showed equally the smallest amount. Nitrate can support the estimation of SIC-originated CO

₂ emission when nitrification is the only source of soil acidification. Dissolved Ca

²⁺ concentration was a more robust proxy than NO

₃

^- for quantification of SIC-originated CO

₂ emission in our batch experiment, however, more evidences have to be collected before using Ca

²⁺ as a proxy in open soil systems. Verification of the δ

¹³C values by dissolved Ca

²⁺ showed that the contribution of SIC to the total CO

₂ emission is overestimated after organic N fertilization, whereas an underestimation in the contribution of SIC to the soil CO

₂ emission was observed after inorganic N fertilization. In summary, the δ

¹³C analysis could yield inaccurate results regarding the effects of N fertilization on the contribution of SIC in soil CO

₂ emission which should be considered in the future studies. From an environmental point of view, it can be concluded that when the amounts of N, especially in ammonium form e.g. amino groups are relatively high in organic fertilizers as it was the case in liquid pig manure compared to inorganic fertilizers, organic and inorganic N fertilizers lead to comparable amounts of SIC loss. This should be considered in applying organic fertilizers as a sustainable strategy to slow down the rate of soil acidification.

Organisation(s)

Soil Science Section
Institute of Soil Science
Section Soil Chemistry

Type

Article

Journal

GEODERMA

Volume

457

ISSN

0016-7061

Publication date

05.2025

Publication status

Published

Peer reviewed

Yes

ASJC Scopus subject areas

Soil Science

Sustainable Development Goals

SDG 2 - Zero Hunger

Electronic version(s)

https://doi.org/10.1016/j.geoderma.2025.117309 (Access: Open)