Characterization and application of biochar derived from greenhouse crop by-products for soil improvement and crop productivity in South Korea

IF 2.3 3区农林科学 Q3 FOOD SCIENCE & TECHNOLOGY Applied Biological Chemistry Pub Date : 2024-12-23 DOI:10.1186/s13765-024-00968-6

Yu Na Lee, Sin Sil Kim, Dong Won Lee, Jae Hong Shim, Sang Ho Jeon, Ahn Sung Roh, Soon Ik Kwon, Dong-Cheol Seo, Seong Heon Kim

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Abstract

The study examined the optimal production conditions and application rates of biochar derived from greenhouse crop by-products to enhance soil improvement and increase crop yield, thereby promoting sustainable agriculture in South Korea. The expansion of greenhouse cultivation has resulted in significant waste management challenges, and biochar production has emerged as a promising recycling solution for these by-products. Biochar was produced from red pepper stalks through pyrolysis at 200 to 600 °C, and its chemical properties, including pH, EC, T-C, and T-N, were analyzed. In this study, the chemical properties of biochar showed a significant increase in pH (from 5.8 to 10.3), EC (from 46.0 to 119.5 dS m⁻¹), and T-C (from 47.7 to 63.1%) with rising pyrolysis temperatures, while T-N decreased due to nitrogen volatilization above 300 °C. In the lettuce cultivation experiment, biochar application significantly improved fresh weight yield, with the biochar-treated group achieving a maximum of 83.3 g pot^− 1 in the first cropping season, compared to 62.8 g pot^− 1 in the NPK-only treatment group. However, excessive biochar application rates (≥ 800 kg ha⁻¹) led to yield reductions in the second cropping season, likely due to increased soil pH and EC. These results suggest the potential of recycling greenhouse crop residues into biochar to enhance soil fertility and crop productivity while indicating the need to manage application rates to minimize negative impacts from excessive use.

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韩国温室作物副产品生物炭在土壤改良和作物生产力方面的特性和应用

该研究考察了从温室作物副产品中提取生物炭的最佳生产条件和施用量，以加强土壤改良和提高作物产量，从而促进韩国的可持续农业。温室种植的扩大带来了重大的废物管理挑战，而生物炭生产已成为这些副产品的有希望的回收解决方案。以红辣椒秸秆为原料，在200 ~ 600℃条件下热解制得生物炭，并对其pH、EC、T-C、T-N等化学性质进行了分析。在这项研究中,生物炭的化学性质有显著提高的pH值(从5.8到10.3),电子商务(从46.0到119.5 dS米⁻¹),和温度系数(从47.7到63.1%)热解温度上升,而sn由于氮挥发减少超过300°C。在生菜栽培试验中，施用生物炭显著提高了生菜鲜重产量，在第一种植季，生物炭处理组的鲜重产量最高可达83.3 g pot - 1，而仅施用氮磷钾组的鲜重产量最高可达62.8 g pot - 1。然而，过量的生物炭施用量（≥800 kg ha⁻¹）导致第二种植季的产量下降，可能是由于土壤pH和EC的增加。这些结果表明，将温室作物秸秆转化为生物炭具有提高土壤肥力和作物生产力的潜力，同时也表明需要管理施用量，以尽量减少过度使用造成的负面影响。

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来源期刊

Applied Biological Chemistry Chemistry-Organic Chemistry

CiteScore

5.40

自引率

6.20%

发文量

审稿时长

20 weeks

期刊介绍： Applied Biological Chemistry aims to promote the interchange and dissemination of scientific data among researchers in the field of agricultural and biological chemistry. The journal covers biochemistry and molecular biology, medical and biomaterial science, food science, and environmental science as applied to multidisciplinary agriculture.