Carbon and nutrient cycling responses to repeated application of biochar and NPK fertilizers depend on microenvironmental differences among hierarchical aggregate fractions

IF 2 3区 农林科学 Q3 ECOLOGY
Chinyere Blessing Okebalama , Bernd Marschner
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引用次数: 0

Abstract

The conversion of bambara groundnut seed residues into biochar facilitated the bioavailability and retention of more nutrients (C, N, P, K and Mg) after repeated application of biochar. However, the mechanisms of microbially mediated biochar-C degradation and nutrient cycling responses to repeated biochar application, particularly in different hierarchical soil aggregates, are largely unknown. A 20-day incubation experiment was conducted on Ultisols from a 4-year cucumber field trial in Nsukka, Nigeria. The effects of repeated application of bambara seed residue biochar with or without NPK fertilizer on soil aggregate associated electrical conductivity (EC), basal respiration, microbial biomass, and soil enzyme activities were determined. The results showed that the concentration of organic matter in the bulk soils increased with biochar and NPK+biochar treatments. These treatments also increased the soil EC, cumulative CO2 respiration, microbial biomass C and N concentrations, and the activities of tyrosine-aminopeptidase and sulfatase enzymes, compared to the biochar treatment and the control soil. The NPK+biochar treatment contributed 35 % more to β-cellobiosidase activity, but the biochar treatment resulted in 85 % reduction in N-Acetyl-β-glucosaminidase activity, indicating microbial N mining. The NPK and NPK+biochar treatments accounted for a higher percentage of N-, C and N-, and S- cycle enzyme activities, although their composition was relatively higher with the latter treatment. The overall soil biochemical responses were significantly higher in the micro-aggregates (< 0.25 mm) than in the macro-aggregates (≤ 4.75–0.25 mm); least of all in the small macro-aggregates (0.25–1.00 mm). Therefore, repeated application of biochar to N-deficient soils generally does not result in positive soil biochemical responses. However, repeated application of biochar together with NPK fertilizer modulates N limitation and optimizes microbial nutrient cycling processes, especially in micro-aggregates.

重复施用生物炭和氮磷钾化肥的碳和养分循环响应取决于分级骨料组分之间的微环境差异
将班巴拉花生种子残渣转化为生物炭,有利于重复施用生物炭后更多养分(碳、氮、磷、钾和镁)的生物利用率和保留率。然而,微生物介导的生物炭-碳降解机制以及重复施用生物炭后的养分循环反应,尤其是在不同层次的土壤团聚体中的反应,在很大程度上还不为人所知。我们在尼日利亚恩苏卡为期 4 年的黄瓜田间试验的 Ultisols 上进行了为期 20 天的培养实验。实验测定了在施用或不施用氮磷钾化肥的情况下重复施用班巴拉种子残渣生物炭对土壤团聚体相关导电率(EC)、基础呼吸、微生物生物量和土壤酶活性的影响。结果表明,生物炭和 NPK+ 生物炭处理增加了土壤中有机质的浓度。与生物炭处理和对照土壤相比,这些处理还提高了土壤导电率、累积二氧化碳呼吸量、微生物生物量的碳和氮浓度以及酪氨酸-氨基肽酶和硫酸根酶的活性。氮磷钾+生物炭处理使β-纤维生物糖苷酶活性提高了35%,但生物炭处理导致N-乙酰基-β-氨基葡萄糖酶活性降低了85%,这表明微生物在开采氮。氮磷钾处理和氮磷钾+生物炭处理的 N-、C-、N-和 S-循环酶活性所占比例较高,但后者的酶活性组成相对较高。微团聚体(< 0.25 mm)的整体土壤生化反应明显高于大团聚体(≤ 4.75-0.25 mm);小团聚体(0.25-1.00 mm)的反应最小。因此,在缺氮土壤中重复施用生物炭一般不会产生积极的土壤生化反应。不过,重复施用生物炭和氮磷钾肥可以调节氮限制,优化微生物养分循环过程,尤其是在微团聚体中。
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来源期刊
Pedobiologia
Pedobiologia 环境科学-生态学
CiteScore
4.20
自引率
8.70%
发文量
38
审稿时长
64 days
期刊介绍: Pedobiologia publishes peer reviewed articles describing original work in the field of soil ecology, which includes the study of soil organisms and their interactions with factors in their biotic and abiotic environments. Analysis of biological structures, interactions, functions, and processes in soil is fundamental for understanding the dynamical nature of terrestrial ecosystems, a prerequisite for appropriate soil management. The scope of this journal consists of fundamental and applied aspects of soil ecology; key focal points include interactions among organisms in soil, organismal controls on soil processes, causes and consequences of soil biodiversity, and aboveground-belowground interactions. We publish: original research that tests clearly defined hypotheses addressing topics of current interest in soil ecology (including studies demonstrating nonsignificant effects); descriptions of novel methodological approaches, or evaluations of current approaches, that address a clear need in soil ecology research; innovative syntheses of the soil ecology literature, including metaanalyses, topical in depth reviews and short opinion/perspective pieces, and descriptions of original conceptual frameworks; and short notes reporting novel observations of ecological significance.
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