Assessing biochar's impact on greenhouse gas emissions, microbial biomass, and enzyme activities in agricultural soils through meta-analysis and machine learning
Jinze Bai, Bruno Rafael de Almeida Moreira, Yuxin Bai, Cresha Gracy Nadar, Yongzhong Feng, Sudhir Yadav
Abstract
The role of biochar in reducing greenhouse gas (GHG) emissions and improving soil health is a topic of extensive research, yet its effects remain debated. Conflicting evidence exists regarding biochar's impact on soil microbial-mediated emissions with respect to different GHGs. This study systematically examines these divergent perspectives, aiming to investigate biochar's influence on GHG emissions and soil health in agricultural soils. The meta-analysis includes 2594 paired observations from 157 studies conducted between 2000 and 2024. It was found that biochar increased the presence of amoA and nosZ genes by 39.4 % and 41.7 %, respectively, while reducing the abundance of the nirS gene by 17.8 %. This led to a 13.1 % decrease in N 2 O emissions. Nitrous emissions were positively associated with mean annual temperature and biochar's pyrolysis temperature and dosage while inversely related to soil pH, nitrogen fertilisation rate, and biochar pH and carbon content. Biochar also regulated enzyme activity related to the nutrient cycle and increased microbial biomass carbon, nitrogen, and phosphorus by 16.6 %, 23.9 %, and 50.2 %, respectively, leading to changes in microbial community diversity. These changes contributed to a reduction in CO 2 and CH 4 emissions, particularly when biochar and nitrogen fertiliser were applied at doses below 21.4 t ha −1 and 242.5 kg ha −1 , as predicted by machine learning models. This study offers an overview of the positive impact of biochar amendments on soil GHG emissions mitigation. The key predictive factors identified could help optimise biochar production and targeted amendments, potentially improving soil health and achieving carbon neutrality in agroecosystems. • Biochar reduced N 2 O and CH 4 emissions by 13.1 % and 6.8 %, respectively. • Low-dose biochar combined with residue in high pH soils decreased CO 2 fluxes. • Dosage, N application rate, and MAT influenced biochar's impact on GHG emissions. • GHG emissions associated positively with biochar dosage but negatively with N rate. • Microbial biomass C and bacterial diversity were key contributors to GHG changes.