Special Microbial Communities Enhanced the Role of Aged Biochar in Reducing Cd Accumulation in Rice

Deng, Xueyun; Long, Changzhi; Chen, Le; Du, Yanli; Zhang, Zhengwei; Gan, L. H.; Zeng, Yongjun

doi:10.3390/agronomy13010081

Cited by 2 publications

(2 citation statements)

References 56 publications

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“…In rice, after four years of biochar application, its effectiveness can only be felt because it can help the work of four bacteria in adding nutrients and immobilizing heavy metals. The related bacteria are Proteobacteria (including the Rhodocyclaceae, Burkholderiaceae, and Nitrosomonadaceae families), Chloroflexi (including the Anaerolineaceae family), Bacteroidetes (including the Ignavibacteriales and Bacteroidales orders), and Nitrospirae (Wang et al, 2019;Deng et al, 2022). Thus, the effectiveness of banana waste biochar in reducing Pb, Cu, and Cd in soil and plants needs to be assessed regularly.…”

Section: Discussionmentioning

confidence: 99%

Utilization of banana waste biochar to reduce heavy metal contamination in soil and maize plants

Wedayani,

Rai,

Mahardika

et al. 2024

J. Degrade. Min. Land Manage.

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There are indications of heavy metal contamination in soil and agricultural products on paddy fields in Subak Kerdung, Bali. Soil amendments are needed to reduce heavy metal content in contaminated soil to minimize heavy metals in plants. Biochar that contains high organic carbon material and is highly resistant to decomposition is claimed to inhibit and reduce the content of heavy metals in soil and plants. Banana wastes containing cellulose and lignin are considered good as biochar raw materials. This research that aimed to observe the ability of banana waste biochar to reduce heavy metals in soil taken from Subak Kerdung, Bali, was conducted in a greenhouse using maize plants as control plants. The treatments tested consisted of two factors. The first factor was the type of banana waste as biochar-making material consisting of banana stem biochar, banana peel biochar, banana fruit bunch biochar, and mixed biochar (banana stem + banana peel + banana fruit bunch). The second factor was the biochar dosage, which consists of four contents, namely 0 t/ha, 5 t/ha, 10 t/ha, and 15 t/ha. All treatment combinations were arranged in a two-factor, randomized block design with three replications. The results showed that mixed biochar (banana stem + banana peel + banana fruit bunch) effectively reduced Pb and Cu in maize plants. In contrast, banana peel biochar could optimally reduce Cd content in soil and its content in plants. Based on the dose, 15 t/ha of mixed biochar reduced Pb and Cd contents, while 10 t/ha of mixed biochar reduced Cu content.

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Section: Discussionmentioning

confidence: 99%

Utilization of banana waste biochar to reduce heavy metal contamination in soil and maize plants

Wedayani,

Rai,

Mahardika

et al. 2024

J. Degrade. Min. Land Manage.

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“…Cadmium (Cd) is one of the most toxic heavy metal pollutants in farmland soil worldwide [1]. The limited values of Cd content are different in different countries and for different types of soils with different pH.…”

Section: Introductionmentioning

confidence: 99%

Effects of Biochar on the Cd Uptake by Rice and the Cd Fractions in Paddy Soil: A 3-Year Field Experiment

et al. 2023

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Biochar is a potential amendment for the remediation of Cd-contaminated soils. Although the immobilization effect of biochar on soil Cd has been studied under indoor laboratory conditions, the effect of biochar on rice Cd uptake and soil Cd fractions under field conditions is still poorly understood. Here, the Cd content of the different organs of rice and the Cd fractions in soil were characterized for three years after the application of different amounts of biochar (0, 7.5, 15, 30 t ha−1, and 3 t ha−1 year−1). The Cd content of brown rice, husk, leaf, stem and sheath, and root under biochar treatment could be maximally reduced by up to 26.25%, 20.16%, 20.74%, 33.2%, and 26.89%, respectively. Biochar altered the Cd fractions in soil, including the decrease in exchangeable Cd content and the increase in Fe-Mn oxide bound Cd and organic bound Cd. The concentration factor of Cd uptake by rice was reduced by 32% under biochar application, while biochar had little influence on the transfer factor and distribution factor. The immobilization effect of biochar on soil Cd lasted for at least three years, but the trend of Cd immobilization efficiency over time for different amounts of biochar treatment was different. The Risk Assessment Code (RAC) of Cd in soil with biochar amendment could be reduced to a medium risk level from a high risk level. Redundancy analysis (RDA) revealed that changes in soil pH and Fe-Mn oxide bound Cd content caused by biochar application contributed most to the reduction in the Cd content of rice organs. These findings would enhance our understanding of the immobilization effect of biochar on Cd in paddy soil under field conditions.

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Special Microbial Communities Enhanced the Role of Aged Biochar in Reducing Cd Accumulation in Rice

Cited by 2 publications

References 56 publications

Utilization of banana waste biochar to reduce heavy metal contamination in soil and maize plants

Utilization of banana waste biochar to reduce heavy metal contamination in soil and maize plants

Effects of Biochar on the Cd Uptake by Rice and the Cd Fractions in Paddy Soil: A 3-Year Field Experiment

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