Magnesium-doped biochars increase soil phosphorus availability by regulating phosphorus retention, microbial solubilization and mineralization

IF 13.1 2区环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES

Biochar Pub Date : 2024-07-18 DOI:10.1007/s42773-024-00360-z

Muhammed Mustapha Ibrahim, Huiying Lin, Zhaofeng Chang, Zhimin Li, Asif Riaz, Enqing Hou

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Abstract

Despite fertilization efforts, phosphorus (P) availability in soils remains a major constraint to global plant productivity. Soil incorporation of biochar could promote soil P availability but its effects remain uncertain. To attain further improvements in soil P availability with biochar, we developed, characterized, and evaluated magnesium-oxide (MgO) and sepiolite (Mg₄Si₆O₁₅(OH)₂·6H₂O)-functionalized biochars with optimized P retention/release capacity. Field-based application of these biochars for improving P availability and their mechanisms during three growth stages of maize was investigated. We further leveraged next-generation sequencing to unravel their impacts on the plant growth-stage shifts in soil functional genes regulating P availability. Results showed insignificant variation in P availability between single super phosphate fertilization (F) and its combination with raw biochar (BF). However, the occurrence of Mg-bound minerals on the optimized biochars’ surface adjusted its surface charges and properties and improved the retention and slow release of inorganic P. Compared to BF, available P (AP) was 26.5% and 19.1% higher during the 12-leaf stage and blister stage, respectively, under MgO-optimized biochar + F treatment (MgOBF), and 15.5% higher under sepiolite-biochar + F (SBF) during maize physiological maturity. Cumulatively, AP was 15.6% and 13.2% higher in MgOBF and SBF relative to BF. Hence, plant biomass, grain yield, and P uptake were highest in MgOBF and SBF, respectively at harvest. Optimized-biochar amendment stimulated microbial 16SrRNA gene diversity and suppressed the expression of P starvation response and P uptake and transport-related genes while stimulating P solubilization and mineralization genes. Thus, the optimized biochars promoted P availability via the combined processes of slow-release of retained phosphates, while inducing the microbial solubilization and mineralization of inorganic and organic P, respectively. Our study advances strategies for reducing cropland P limitation and reveals the potential of optimized biochars for improving P availability on the field scale.

Graphical Abstract

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掺镁生物炭通过调节磷的保留、微生物溶解和矿化，增加土壤中磷的可用性

尽管努力施肥，但土壤中磷（P）的可用性仍然是全球植物生产力的主要制约因素。在土壤中加入生物炭可以提高土壤中磷的可用性，但其效果仍不确定。为了利用生物炭进一步提高土壤磷的可用性，我们开发、鉴定并评估了具有优化磷保留/释放能力的氧化镁（MgO）和海泡石（Mg4Si6O15(OH)2-6H2O）功能化生物炭。我们研究了这些生物酵母在田间的应用，以提高玉米三个生长阶段的钾可用性及其机理。我们进一步利用下一代测序技术，揭示了这些生物螯合剂对调节钾供应的土壤功能基因在植物生长阶段变化的影响。结果表明，单一施用过磷酸钙肥料（F）与施用过磷酸钙肥料和未加工生物炭（BF）之间的钾供应量差异不大。与 BF 相比，在玉米生理成熟期，氧化镁优化生物炭 + F 处理（MgOBF）在 12 叶期和水泡期的可利用钾（AP）分别比 BF 高 26.5%和 19.1%，在海泡石生物炭 + F 处理（SBF）下高 15.5%。与 BF 相比，MgOBF 和 SBF 的总产量分别高出 15.6% 和 13.2%。因此，收获时，MgOBF 和 SBF 的植株生物量、谷物产量和钾吸收量分别最高。优化的生物炭改良剂刺激了微生物 16SrRNA 基因的多样性，抑制了钾饥饿反应和钾吸收及运输相关基因的表达，同时刺激了钾溶解和矿化基因的表达。因此，优化后的生物酵素通过缓释保留的磷酸盐，同时分别诱导微生物对无机钾和有机钾的溶解和矿化，促进了钾的供应。我们的研究推进了减少耕地钾限制的战略，并揭示了优化生物酵素在提高田间钾利用率方面的潜力。图文摘要

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来源期刊

Biochar Multiple-

CiteScore

18.60

自引率

10.20%

发文量

期刊介绍： Biochar stands as a distinguished academic journal delving into multidisciplinary subjects such as agronomy, environmental science, and materials science. Its pages showcase innovative articles spanning the preparation and processing of biochar, exploring its diverse applications, including but not limited to bioenergy production, biochar-based materials for environmental use, soil enhancement, climate change mitigation, contaminated-environment remediation, water purification, new analytical techniques, life cycle assessment, and crucially, rural and regional development. Biochar publishes various article types, including reviews, original research, rapid reports, commentaries, and perspectives, with the overarching goal of reporting significant research achievements, critical reviews fostering a deeper mechanistic understanding of the science, and facilitating academic exchange to drive scientific and technological development.