Role of phytolith occluded carbon of cereales plants for climate change mitigation

Q2 Social Sciences Journal of Water and Land Development Pub Date : 2024-03-21 DOI:10.24425/jwld.2023.148459

B. Rutkowska, Peter Schröder, Michel Mench, Francois Rineau, Witold Szulc, W. Szulc, J. Pobereżny, Kristjan Tiideberg, Tomasz Niedziński, E. Loit

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Abstract

Phytolith-occluded carbon (PhytOC) is highly stable, and constitutes an important source of long-term C storage in agrosystems. This stored carbon is resistant to the processes of oxidation of carbon compounds. In our research phytolith content in barley (Estonia) and oat (Poland) grain and straw was assessed at field trials, with Si as a liquid immune stimulant OPTYSIL and compost fertilisation. We showed that cereals can produce relatively high amounts of phytoliths. PhytOC plays a key role in carbon sequestration, particularly for poor, sandy Polish and Estonian soils. The phytolith content was always higher in straw than in grain regardless of the type of cereals. The phytolith content in oat grains varied from 18.46 to 21.28 mg∙g−1 DM, and in straw 27.89–38.97 mg∙g−1 DM. The phytolith content in barley grain ranged from 17.24 to 19.86 mg∙g−1 DM, and in straw from 22.06 to 49.08 mg∙g−1 DM. Our results suggest that oat ecosystems can absorb from 14.94 to 41.73 kg e-CO2∙ha−1 and barley absorb from 0.32 to 1.60 kg e-CO2∙ha−1. The accumulation rate of PhytOC can be increased 3-fold in Polish conditions through foliar application of silicon, and 5-fold in Estonian conditions. In parallel, the compost fertilisation increased the phytolith content in cereals.

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禾本科植物的植被覆盖碳对减缓气候变化的作用

植物溶解碳（PhytOC）高度稳定，是农业系统中长期储存碳的重要来源。这种储存的碳可以抵抗碳化合物的氧化过程。在我们的研究中，大麦（爱沙尼亚）和燕麦（波兰）谷物和秸秆中的植物石含量在田间试验中进行了评估，并将 Si 用作液体免疫促进剂 OPTYSIL 和堆肥。结果表明，谷物可以产生相对较多的植化素。植物有机碳（PhytOC）在固碳方面发挥着关键作用，尤其是在波兰和爱沙尼亚的贫瘠沙质土壤中。无论谷物的种类如何，秸秆中的植生石含量总是高于谷物。燕麦颗粒中的植物石含量在 18.46 到 21.28 mg∙g-1 DM 之间变化，秸秆中的植物石含量在 27.89 到 38.97 mg∙g-1 DM 之间变化。大麦粒中的植金石含量为 17.24-19.86 mg∙g-1 DM，秸秆中的植金石含量为 22.06-49.08 mg∙g-1 DM。我们的研究结果表明，燕麦生态系统可吸收 14.94 至 41.73 千克二氧化碳当量/公顷，大麦可吸收 0.32 至 1.60 千克二氧化碳当量/公顷。通过叶面喷施硅，植物有机碳的积累率在波兰条件下可提高 3 倍，在爱沙尼亚条件下可提高 5 倍。与此同时，堆肥也增加了谷物中的植物石含量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Water and Land Development Social Sciences-Development

CiteScore

2.10

自引率

0.00%

发文量

审稿时长

14 weeks

期刊介绍： Journal of Water and Land Development - is a peer reviewed research journal published in English. Journal has been published continually since 1998. From 2013, the journal is published quarterly in the spring, summer, autumn, and winter. In 2011 and 2012 the journal was published twice a year, and between 1998 and 2010 it was published as a yearbook. . Papers may report the results of experiments, theoretical analyses, design of machines and mechanization systems, processes or processing methods, new materials, new measurements methods or new ideas in information technology. Topics: engineering and development of the agricultural environment, water managment in rural areas and protection of water resources, natural and economic functions of grassland.