# Sugarcane cultivation reduces charcoal C and Al/Fe-bound OC in selected Ferralsols

**Authors:** Nontokozo Pertunia Mkhonza, Pardon Muchaonyerwa

PMC · DOI: 10.1007/s10661-025-13924-8 · 2025-03-31

## TL;DR

Sugarcane farming decreases charcoal carbon and aluminum/iron-bound organic carbon in Ferralsols compared to forested areas.

## Contribution

The study reveals how sugarcane cultivation affects soil carbon stabilization mechanisms in Ferralsols.

## Key findings

- Sugarcane cultivation reduced charcoal C and Al/Fe-bound OC compared to forest soils.
- Al/Fe-bound OC was the primary mechanism for OC stabilization in Ferralsols.
- Charcoal C stocks decreased with depth only in sugarcane soils.

## Abstract

Long-term sugarcane cultivation, with pre-harvest burning, may add recalcitrant charcoal carbon (C) to soil organic carbon (OC) in Ferralsols, whereas aluminium/iron-organic matter (Al/Fe-OM) complexes may dominate the mineral-associated OC in these soils. Therefore, the objective of this study was to examine the effect of sugarcane cultivation relative to wattle forest on soil OC in charcoal C form and Al/Fe-OM complexes on two selected Ferralsols. Total C, charcoal C, and Al/Fe-OC were analysed in samples collected from the two sites under forest and sugarcane cultivation to a depth of 100 cm, and the data were subjected to a two-way analysis of variance. At both sites, sugarcane cultivation reduced charcoal C and Al/Fe-bound OC when compared to forest. The Al/Fe-bound OC in sugarcane soils accounted for 48.7 and 72.2% of the total OC at Eston and Wartburg sites, respectively. In forest soils, the Al/Fe-bound OC accounted for 45.6 and 44.4% of the total OC at Eston and Wartburg, respectively. Charcoal C accounted for 8.42 and 4.07% of the total OC in sugarcane soils, at Eston and Wartburg, respectively. Overall, charcoal C concentration decreased with increase in soil depth, while its stocks only decreased with depth in soil under sugarcane. The Al/Fe-bound OC decreased with an increase in soil depth for both land uses, while Alp and Alp + Fep concentrations were not affected by sampling depth. These findings demonstrate that OC in Al/Fe-OC complexes and charcoal C contribute to the high OC concentrations, with Al/Fe-bound OC fraction being the primary mechanism of OC stabilisation in these Ferralsols, while sugarcane cultivation reduces these concentrations.

## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/PMC11958378/full.md

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Source: https://tomesphere.com/paper/PMC11958378