Biochar, a carbon-rich material derived from biomass, is widely recognized for its potential to improve soil health and sequester carbon. However, its impact on soil carbon dynamics has been inconsistent across different soil types. Recent research published in Biochar reveals a critical chemical mechanism underlying these variable effects: biochar-derived hydroxyl radicals that suppress soil enzymes responsible for organic carbon decomposition.
The study, led by Shuping Qin and colleagues from Shenyang Agricultural University, investigated wheat-straw biochar’s influence on three distinct Chinese soils—Fluvo-aquic, Black, and Red soils. These soils vary considerably in pH and mineral composition, providing an ideal framework to explore soil-specific responses. The researchers compared untreated biochar, which contains persistent free radicals, with chemically modified biochar where these radicals were quenched. They also employed targeted removal of hydroxyl radicals to assess their direct effects on soil carbon transformation.
In acidic, mineral-rich Black and Red soils, untreated biochar significantly reduced carbon dioxide emissions by 6.8% and 12.9% respectively. This reduction was accompanied by a suppression of key extracellular enzymes involved in breaking down soil organic matter. Quenching the biochar’s free radicals reversed this effect, leading to heightened enzyme activity and increased respiration rates. Similar increases in enzyme activity and soil carbon loss were observed when hydroxyl radicals were directly removed from the soil, firmly establishing their role in enzyme inhibition.
The biochemical mechanism proposed is that biochar-derived hydroxyl radicals interact with and damage extracellular enzymes, limiting microbial decomposition of native organic carbon. This enzymatic suppression slows mineralization rates and enhances carbon retention specifically in acidic soils with abundant minerals capable of interacting with free radicals. This nuanced interaction challenges the simplistic assumption of biochar solely as a stable carbon input.
Contrastingly, in the Fluvo-aquic soil, biochar incorporation led to increased carbon dioxide emissions. Here, stimulation of microbial metabolism and organic matter decomposition appeared to outweigh any enzyme suppression. This soil-specific divergence underscores how factors such as soil pH, mineralogy, and microbial community composition can modulate biochar’s net effect on carbon cycling.
These findings emphasize that biochar amendments must be tailored to soil type rather than applied universally. The chemical properties of biochar—including its production conditions and feedstock—and the native soil environment collectively determine whether biochar mediates carbon sequestration or accelerates carbon loss.
By unveiling the role of reactive oxygen species in modifying enzyme activity, this study provides an important chemical explanation for the heterogeneous effects of biochar on soil carbon. These insights offer a pathway to designing soil-specific biochar utilization strategies, advancing the potential of biochar not only as a soil conditioner but also as a climate mitigation tool in sustainable agriculture.
Subject of Research: Biochar chemistry and soil carbon cycling
Article Title: Soil-specific protection of organic carbon by biochar-derived hydroxyl radicals associated with enzyme suppression
News Publication Date: 6-Jul-2026
Web References: http://dx.doi.org/10.1007/s42773-026-00641-9
References: Wu, P., Fu, Y., Wang, H. et al. Soil-specific protection of organic carbon by biochar-derived hydroxyl radicals associated with enzyme suppression. Biochar 8, 126 (2026).
Image Credits: Ping Wu, Yingdong Fu, Hailong Wang & Shuping Qin
Keywords: Biochar, Soil carbon, Hydroxyl radicals, Enzyme suppression, Soil-specific effects, Carbon sequestration, Soil microbiology
Tags: biochar chemical modificationsbiochar hydroxyl radicalsbiochar soil carbon sequestrationbiochar-induced changes in soil microbial activitybiochar’s role in soil healthbiomass-derived soil amendmentscarbon dioxide emission reductioneffect of biochar on different soil typessoil enzyme activity suppressionsoil organic matter decompositionsoil pH and mineral influence on biochar impactvariable effects of biochar in agricultural soils



