Influence of (nano-)biochar-based fertilizer on rice plant growth and metal(oild) uptake under the co-exposure of cadmium and arsenic in a life-cycle greenhouse study

Xingyu Yan , Jing Liu , Wenhui Li , Weiying Feng , Jiawei Wang , Zhongxiang Cao , Jining Li , John P. Giesy , George P. Cobb

Biochar ›› 2026, Vol. 8 ›› Issue (1) : 54

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Biochar ›› 2026, Vol. 8 ›› Issue (1) :54 DOI: 10.1007/s42773-026-00571-6
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Influence of (nano-)biochar-based fertilizer on rice plant growth and metal(oild) uptake under the co-exposure of cadmium and arsenic in a life-cycle greenhouse study

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Abstract

The low fertilizer utilization efficiency and metal(loid) contamination have become dual challenges that constrain the production of rice and thus food security. To address these issues, a life-cycle greenhouse study was conducted with rice (Oryza sativa) grown in soil co-contaminated with cadmium (Cd) and arsenic (As) and treated with several synthetic fertilizers. These fertilizers included regular fertilizers (F), biochar-based fertilizers (BF) and nano-biochar-based fertilizers (NBF), each formulated with varying nitrogen:phosphorus:potassium (N:P:K) ratios (I, II, and III). The results revealed a differential suppression of Cd (strongest under F-I, followed by NBF-III) and As (strongest under F-II, followed by NBF-I) in rice grains, attributable to disparities in their environmental chemistry, bioavailability, and plant-mediated uptake and translocation mechanisms. While BF enhanced catalase and alkaline phosphatase activities, NBF more effectively stimulated urease activity throughout the 0–10 cm layer and sucrase activity in the deeper 5–10 cm zone. Notably, NBF increased soil metabolic diversity under Cd and As stress while strengthening the genetic regulatory capacity and environmental adaptability of microbial communities. Furthermore, NBF dynamically regulated the migration of Cd and As into porewater, resulting in more stable and effective immobilization compared to BF and F treatments. These findings highlight that the application of biochar, particularly nano-biochar, for paddy soil remediation necessitates a contaminant-specific and nutrient-managed strategy. Tailoring both the biochar type and the accompanying N:P:K ratio is crucial for targeting the biogeochemical behavior of the dominant contaminant, thereby ensuring grain safety and supporting sustainable rice production.

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Keywords

Controlled-release fertilizer / Co-contamination / Porewater dynamics / Soil enzymes / Microbial community / N:P:K stoichiometry

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Xingyu Yan, Jing Liu, Wenhui Li, Weiying Feng, Jiawei Wang, Zhongxiang Cao, Jining Li, John P. Giesy, George P. Cobb. Influence of (nano-)biochar-based fertilizer on rice plant growth and metal(oild) uptake under the co-exposure of cadmium and arsenic in a life-cycle greenhouse study. Biochar, 2026, 8(1): 54 DOI:10.1007/s42773-026-00571-6

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Bolan N, Sarmah A, Bordoloi Set al.. Soil acidification and the liming potential of biochar. Environ Pollut, 2023, 317 120632
[2]

Cao X, Liu J, Zhang Let al.. Response of soil microbial ecological functions and biological characteristics to organic fertilizer combined with biochar in dry direct-seeded paddy fields. Sci Total Environ, 2024, 948 174844
[3]

Chausali N, Saxena J, Prasad R. Nanobiochar and biochar based nanocomposites: advances and applications. J Agric Food Res, 2021, 5 100191
[4]

Chen S, Yang M, Ba Cet al.. Preparation and characterization of slow-release fertilizer encapsulated by biochar-based waterborne copolymers. Sci Total Environ, 2018, 615: 431-437

[5]

Chen S, Tang X, Chen Jet al.. Regulation of slow-release performance of high-sugar biomass waste filter mud and sugarcane bagasse by co-hydrothermal carbonization and potential evaluation of hydrochar-based slow-release fertilizers. Biomass Bioenerg, 2025, 193 107557
[6]

Cheng J, Liao Z, Hu SCet al.. Synthesis of an environmentally friendly binding material using pyrolysis by-products and modified starch binder for slow-release fertilizers. Sci Total Environ, 2022, 819 153146
[7]

Cui Z, Zhang H, Chen Xet al.. Pursuing sustainable productivity with millions of smallholder farmers. Nature, 2018, 555: 363-366

[8]

Das KP, Satapathy BK. Highly porous agro-augmenting urea-biochar/polylactic acid-based microfibrous electrospun mats as sustainable controlled release fertilizer carriers. ACS Appl Polym Mater, 2024, 6: 6262-6277

[9]

Dong D, Wang C, Van Zwieten Let al.. An effective biochar-based slow-release fertilizer for reducing nitrogen loss in paddy fields. J Soils Sediments, 2019, 20: 3027-3040

[10]

U.S. Environmental Protection Agency (1996) EPA method 3050B: acid digestion of sediments, sludges, and soils. Available via DIALOG. https://www.epa.gov/esam/epa-method-3050b-acid-digestion-sediments-sludges-and-soils
[11]

Faloye OT, Ajayi AE, Alatise MOet al.. Nutrient uptake, maximum yield production, and economic return of maize under deficit irrigation with biochar and inorganic fertiliser amendments. Biochar, 2020, 1: 375-388

[12]

Gai X, Xing W, Cheng Wet al.. Regulatory mechanism of bamboo biochar dosage on cadmium accumulation in Salix psammophila: insights from rhizosphere microbial communities, assembly processes, and interactions. Carbon Res, 2024, 3 72
[13]

Gu W, Zhang W, Xiu Let al.. Soil aggregate variation in two contrasting rice straw recycling systems for paddy soil amendment over two years. Arch Agron Soil Sci, 2023, 69: 3044-3059

[14]

Hao H, Shan Y, Li Pet al.. Heuristic topological graph convolutional network for risk prediction of potentially toxic elements in cultivated soils. Environ Sci Technol, 2025, 59: 16685-16696

[15]

He Q, Li X, Ren Y. Analysis of the simultaneous adsorption mechanism of ammonium and phosphate on magnesium-modified biochar and the slow release effect of fertiliser. Biochar, 2022, 4 25
[16]

Jeffery S, Verheijen FGA, van der Velde Met al.. A quantitative review of the effects of biochar application to soils on crop productivity using meta-analysis. Agric Ecosyst Environ, 2011, 144: 175-187

[17]

Ji H, Abdalkarim SYH, Shen Yet al.. Facile synthesis, release mechanism, and life cycle assessment of amine-modified lignin for bifunctional slow-release fertilizer. Int J Biol Macromol, 2024, 278 134618
[18]

Jin F, Piao J, Miao Set al.. Long-term effects of biochar one-off application on soil physicochemical properties, salt concentration, nutrient availability, enzyme activity, and rice yield of highly saline-alkali paddy soils: based on a 6-year field experiment. Biochar, 2024, 6 40
[19]

Laird DA, Novak JM, Collins HPet al.. Multi-year and multi-location soil quality and crop biomass yield responses to hardwood fast pyrolysis biochar. Geoderma, 2017, 289: 46-53

[20]

Li C, Ji Y, Li E. Understanding the influences of rice starch fine structure and protein content on cooked rice texture. Starch Starke, 2022, 74 2100253
[21]

Li C, Ji Y, Li Eet al.. Interactions between leached amylose and protein affect the stickiness of cooked white rice. Food Hydrocolloids, 2023, 135 108215
[22]

Li P, Yan M, Li Met al.. Migration rules and mechanisms of nano-biochar in soil columns under various transport conditions. Nanomaterials, 2024, 14 1035
[23]

Liang F, Li GT, Lin QMet al.. Crop yield and soil properties in the first 3 years after biochar application to a calcareous soil. J Integr Agric, 2014, 13: 525-532

[24]

Liu J, Wolfe K, Potter PMet al.. Distribution and speciation of copper and arsenic in rice plants (Oryza sativa japonica 'Koshihikari') treated with copper oxide nanoparticles and arsenic during a life cycle. Environ Sci Technol, 2019, 53: 4988-4996

[25]

Liu Q, Tao Y, Cheng Set al.. Relating amylose and protein contents to eating quality in 105 varieties of Japonica rice. Cereal Chem, 2020, 97: 1303-1312

[26]

Liu Q, Wu C, Wei Let al.. Microbial mechanisms of organic matter mineralization induced by straw in biochar-amended paddy soil. Biochar, 2024, 6 18
[27]

Liu Y, Gao C, Wang Yet al.. Vermiculite modification increases carbon retention and stability of rice straw biochar at different carbonization temperatures. J Clean Prod, 2020, 254 120111
[28]

Liu Z, Yuan X, Zhang Zet al.. Revisiting potassium-induced impacts on crop production and soil fertility based on thirty-three Chinese long-term experiments. Field Crops Res, 2025, 322 109732
[29]

López JE, Saldarriaga JF, Tamayo A. Effect of biogas slurry-modified biochar on Cd immobilization, uptake, translocation, and the bioavailability of N, P, and K in soil. J Soil Sci Plant Nutr, 2025, 25: 6281-6293

[30]

Lu J, Li Y, Cai Yet al.. Co-incorporation of hydrotalcite and starch into biochar-based fertilizers for the synthesis of slow-release fertilizers with improved water retention. Biochar, 2023, 5 44
[31]

Lv G, Yang T, Chen Yet al.. Biochar-based fertilizer enhanced Cd immobilization and soil quality in soil-rice system. Ecol Eng, 2021, 171 106396
[32]

Nayak P, Nandipamu TMK, Chaturvedi Set al.. Synthesis, properties, and mechanistic release-kinetics modeling of biochar-based slow-release nitrogen fertilizers and their field efficacy. J Soil Sci Plant Nutr, 2024, 24: 7460-7479

[33]

Qin Y, Li Z, Sun Jet al.. Manganese (II) sulfate affects the formation of iron-manganese oxides in soil and the uptake of cadmium and arsenic by rice. Ecotoxicol Environ Saf, 2023, 263 115360
[34]

Quintela F, Pino S, Silva Fet al.. Arsenic, lead and cadmium concentrations in caudal crests of the yacare caiman (Caiman yacare) from Brazilian Pantanal. Sci Total Environ, 2020, 707 135479
[35]

Raza A, Li Y, Prakash CSet al.. Panomics to manage combined abiotic stresses in plants. Trends Plant Sci, 2025, 30: 1079-1084

[36]

Sani MNH, Amin M, Siddique ABet al.. Waste-derived nanobiochar: a new avenue towards sustainable agriculture, environment, and circular bioeconomy. Sci Total Environ, 2023, 905 166881
[37]

Shahzadi J, Zaib un N, Ali N, et al (2025) Foliar application of nano biochar solution elevates tomato productivity by counteracting the effect of salt stress insights into morphological physiological and biochemical indices. Sci Rep 15:3205. https://doi.org/10.1038/s41598-025-87399-5
[38]

Shi W, Ju Y, Bian Ret al.. Biochar bound urea boosts plant growth and reduces nitrogen leaching. Sci Total Environ, 2020, 701 134424
[39]

Si L, Xie Y, Ma Qet al.. The short-term effects of rice straw biochar, nitrogen and phosphorus fertilizer on rice yield and soil properties in a cold waterlogged paddy field. Sustainability, 2018, 10 537
[40]

Srivastav AL, Patel N, Rani L, Kumar Pet al.. Sustainable options for fertilizer management in agriculture to prevent water contamination: a review. Environ Dev Sustain, 2023, 26: 8303-8327

[41]

Tan T, Xu Y, Liao Xet al.. Formulating new types of rice husk biochar‐based fertilizers for the simultaneous slow‐release of nutrients and immobilization of cadmium. GCB Bioenergy, 2024, 16 e13142
[42]

Tao K, Yu W, Prakash Set al.. High-amylose rice: starch molecular structural features controlling cooked rice texture and preference. Carbohydr Polym, 2019, 219: 251-260

[43]

Tao Y, Feng W, He Zet al.. Utilization of cotton byproduct-derived biochar: a review on soil remediation and carbon sequestration. Environ Sci Eur, 2024, 36 79
[44]

Villada E, Velasquez M, Gómez AMet al.. Combining anaerobic digestion slurry and different biochars to develop a biochar-based slow-release NPK fertilizer. Sci Total Environ, 2024, 927 171982
[45]

Wang L, Wang J, Wang Zet al.. Enhanced antimonate (Sb(V)) removal from aqueous solution by La-doped magnetic biochars. Chem Eng J, 2018, 354: 623-632

[46]

Wang C, Luo D, Zhang Xet al.. Biochar-based slow-release of fertilizers for sustainable agriculture: a mini review. Environ Sci Ecotechnol, 2022, 10 100167
[47]

Wang J, Sun L, Sun Yet al.. Long-term biochar-based fertilizer substitution promotes carbon, nitrogen, and phosphorus acquisition enzymes in dryland soils by affecting soil properties and regulating bacterial community. Appl Soil Ecol, 2025, 206 105801
[48]

Wu Y, Xi X, Tang Xet al.. Policy distortions, farm size, and the overuse of agricultural chemicals in China. Proc Natl Acad Sci USA, 2018, 115: 7010-7015

[49]

Xiang A, Gao Z, Zhang Ket al.. Study on the Cd (II) adsorption of biochar based carbon fertilizer. Ind Crops Prod, 2021, 174 114213
[50]

Xu M, Luo F, Tu Fet al.. Effects of stabilizing materials on soil Cd bioavailability, uptake, transport, and rice growth. Front Environ Sci, 2022, 10 1035960
[51]

Xue J, Verstraete W, Ni B-Jet al.. Rethink biosolids: risks and opportunities in the circular economy. Chem Eng J, 2025, 510 161749
[52]

Yan S, Ren T, Wan Mahari WAet al.. Soil carbon supplementation: improvement of root-surrounding soil bacterial communities, sugar and starch content in tobacco (N. tabacum). Sci Total Environ, 2022, 802 149835
[53]

Yang J, Yang F, Yang Yet al.. A proposal of “core enzyme” bioindicator in long-term Pb-Zn ore pollution areas based on topsoil property analysis. Environ Pollut, 2016, 213: 760-769

[54]

Yuan Y, Liang Y, Cai Het al.. Soil organic carbon accumulation mechanisms in soil amended with straw and biochar: entombing effect or biochemical protection?. Biochar, 2025, 7 33
[55]

Zhang L, He Y, Lin Det al.. Co-application of biochar and nitrogen fertilizer promotes rice performance, decreases cadmium availability, and shapes rhizosphere bacterial community in paddy soil. Environ Pollut, 2022, 308 119624
[56]

Zhang K, Khan Z, Khan MNet al.. The application of biochar improves the nutrient supply efficiency of organic fertilizer, sustains soil quality and promotes sustainable crop production. Food Energy Secur, 2024, 13 e520
[57]

Zhao C, Xu J, Bi Het al.. A slow-release fertilizer of urea prepared via biochar-coating with nano-SiO2-starch-polyvinyl alcohol: formulation and release simulation. Environ Technol Innov, 2023, 32 103264
[58]

Zulfiqar U, Khokhar A, Maqsood MFet al.. Genetic biofortification: advancing crop nutrition to tackle hidden hunger. Funct Integr Genomics, 2024, 24 34

Funding

National Natural Science Foundation of China(42207325)

Shandong University(Young Scholar Future Plan)

the Key Research and Development and Technology Transfer Program of Inner Mongolia Autonomous Region in China(2025YFHH0145)

the Guangdong Foundation for Program of Science and Technology Research(2023B1212060044)

the GDAS' Project of Science and Technology Development(2022GDASZH-2022010104-2)

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