Insights on soil carbon cycling in intercropped maize-forage systems as affected by nitrogen

A - Papers appearing in refereed journals

Vieira-Da-Mota-Neto, L., Barros, J. V. S., Costa, V. E., Galdos, M., Santos, A. R. P. D. and Rosolem, C. A. 2024. Insights on soil carbon cycling in intercropped maize-forage systems as affected by nitrogen. Geoderma. 449 (sept), p. 116998. https://doi.org/10.1016/j.geoderma.2024.116998

AuthorsVieira-Da-Mota-Neto, L., Barros, J. V. S., Costa, V. E., Galdos, M., Santos, A. R. P. D. and Rosolem, C. A.
Abstract

Intercropping maize with forage grasses is an economical and environmentally sound practice that is increasingly being adopted to enhance resilience in tropical agriculture. Although intensifying integrated cropping systems can increase the sequestration of carbon (C) from plant residues, it also unleashes priming of old soil C enhancing C cycling, particularly under nitrogen (N) fertilization. However, the extent of these competing processes in intercropped maize–forage systems is poorly understood. This four-year study assessed whether new C inputs from maize (Zea mays) intercropped with ruzigrass (Urochloa ruziziensis), palisade grass (Urochloa brizantha), or Guinea grass (Megathyrsus maximum) in the presence or absence of N fertilization affect soil aggregation and C cycling in the soil and within macroaggregates (>0.250 mm) and microaggregates (<0.250 mm) down the soil profile. C cycling was assessed by measuring variations in the abundance of the natural isotope 13C. N fertilization of the intercropped maize–forage systems reduced the proportion of aggregates > 2 mm and the mean weight diameter of aggregates by reducing soil pH. Under N fertilization, the geometric mean diameter of aggregates were 42 % larger under palisade than under Guinea grass. New C inputs from intercropping maize with forage grasses promoted C cycling in bulk soil, particulate organic matter (POM), mineral-associated organic matter (MAOM), and macro- and microaggregates, although these effects were restricted to topsoil. No N fertilization increased ruzigrass C input into MAOM with no clear link with 13C enrichment, suggesting that N fertilization does not impair C stabilization in this pool. Aggregates >2 mm and >0.5 mm were key sinks of C and N up to a soil depth of 40 cm in this intercropped system. Our findings provide insights into the extension of C cycling across SOM pools and aggregates, and the role of N management in intercropping maize forage systems.

Keywords13C isotope; Intercropping; Mineral-associated organic matter (MAOM); Particulate organic matter (POM)
Year of Publication2024
JournalGeoderma
Journal citation449 (sept), p. 116998
Digital Object Identifier (DOI)https://doi.org/10.1016/j.geoderma.2024.116998
Open accessPublished as ‘gold’ (paid) open access
Publisher's version
Output statusPublished
Publication dates
Online10 Aug 2024
Publication process dates
Accepted05 Aug 2024
PublisherElsevier
ISSN0016-7061

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