Distinct forms of liquid biochar mineral complex fertilisers differently increase crop yield, nutrient balance and economic return

Negar Omidvar; Stephen Joseph; Lakmini Dissanayake; Michael B. Farrar; Frédérique Reverchon; Russell Burnett; Kane Trubenbacher; Neda Omidvar; Zhihong Xu; Manyun Zhang; Hongdou Liu; Brittany Elliott; Shahla Hosseini Bai

doi:10.1007/s42773-026-00600-4

Biochar ›› 2026, Vol. 8 ›› Issue (1) :94 DOI: 10.1007/s42773-026-00600-4

Original Research

research-article

Distinct forms of liquid biochar mineral complex fertilisers differently increase crop yield, nutrient balance and economic return

Author information +

¹School of Environment and Science, Griffith University, Nathan, 4111, Brisbane, QLD, Australia

²Red de Diversidad Biológica del Occidente Mexicano, Centro Regional del Bajío, Instituto de Ecología, A.C., Pátzcuaro, Michoacán, Mexico

³, Rainbow Bee Eater Pty Ltd, 2712, Berrigan, NSW, Australia

⁴Department of Accounting, Finance and Economics, School of Business, Griffith University, Nathan, 4111, Brisbane, QLD, Australia

⁵Key Laboratory of Arable Land Quality Monitoring and Evaluation, Ministry of Agriculture and Rural Affairs, College of Environmental Science and Engineering, Yangzhou University, 225127, Yangzhou, Jiangsu, China

⁶School of Biology and Environmental Science, Queensland University of Technology Brisbane, 4000, Brisbane, QLD, Australia

⁷Australian Research Centre for Human Evolution, Griffith University, 4111, Brisbane, Australia

⁸School of Materials Science and Engineering, University of New South Wales, 2052, Sydney, Australia

^a s.hosseini-bai@griffith.edu.au

Show less

History +

PDF

Abstract

Sustaining crop yield is a growing challenge due to soil fertility loss and climate change. As a result, fertiliser application is increasing to sustain yield and counteract low fertiliser use efficiency. Developing nutrient-efficient fertilisers, for example by combining biochar with fertilisers, is thus crucially needed. In this context, the development of biochar-mineral complex (BMC) fertilisers into liquefied products suitable for broadacre application is highly innovative. This study aimed to explore the agronomic benefits and economic viability of four novel liquefied BMCs designed for application within a pasture cropping system. The different forms of developed BMCs included two non-enriched BMCs (BMC1 and BMC2) that were micronised using different techniques, a phosphorus (P)-enriched BMC (BMC3), and a nitrogen (N)-enriched BMC (BMC4), all applied both with- and without co-fertilisation. Soil biochemistry, plant NP uptake, NP balances, plant yield and cost–benefit were examined. Pasture yield was significantly higher using BMC1 and BMC3 with co-fertilisation than without, most likely due to improved P availability, as evidenced by positive P balances. Yield was significantly enhanced under BMC4 at 42.20 t ha⁻¹, compared with BMC1 at 21.90 t ha⁻¹, BMC2 at 19.41 t ha⁻¹, BMC3 at 25.81 t ha⁻¹, the fertilised control at 18.75 t ha⁻¹ and non-fertilised control at 11.53 t ha⁻¹. Only BMC4 showed positive NP balances, suggesting that pasture did not absorb N and P from the existing soil reserve. Soil microbial composition and abundance were not affected by the applied BMC treatments in short term. The benefit–cost ratio ranged from 1.94 to 2.54, indicating economic viability of the BMC products and suggesting a great potential of biochar-based fertilisers for wide adoption to other crops.

Graphic abstract

Keywords

Biochar micronisation / Nutrient balance / Nitrogen / Phosphorus / Pasture / Economic feasibility

Cite this article

Download citation ▾

Negar Omidvar, Stephen Joseph, Lakmini Dissanayake, Michael B. Farrar, Frédérique Reverchon, Russell Burnett, Kane Trubenbacher, Neda Omidvar, Zhihong Xu, Manyun Zhang, Hongdou Liu, Brittany Elliott, Shahla Hosseini Bai. Distinct forms of liquid biochar mineral complex fertilisers differently increase crop yield, nutrient balance and economic return. Biochar, 2026, 8(1): 94 DOI:10.1007/s42773-026-00600-4

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Abujabhah IS, Doyle RB, Bound SA, Bowman JP. Assessment of bacterial community composition, methanotrophic and nitrogen-cycling bacteria in three soils with different biochar application rates. J Soils Sediments, 2018, 18(1): 148-158

[2]	Adhikari S, Anuragi H, Chandra K, Tarte SH, Dhaka SR, Jatav HS, Hingonia KAftab T, Hakeem KR. Molecular basis of plant nutrient use efficiency—concepts and challenges for its improvement. Sustainable plant nutrition, 2023, Amsterdam. Elsevier: 107-151

[3]	Adhikari S, Moon E, Timms W. Identifying biochar production variables to maximise exchangeable cations and increase nutrient availability in soils. J Clean Prod, 2024, 446 141454

[4]	Ågren GI, Wetterstedt JM, Billberger MF. Nutrient limitation on terrestrial plant growth—modeling the interaction between nitrogen and phosphorus. New Phytol, 2012, 194(4): 953-960

[5]	Asadyar L, Xu CY, Wallace HM, Xu Z, Reverchon F, Bai SH. Soil-plant nitrogen isotope composition and nitrogen cycling after biochar applications. Environ Sci Pollut Res Int, 2021, 28(6): 6684-6690

[6]	Bai SH, Reverchon F, Xu C-Y, Xu Z, Blumfield TJ, Zhao H, Van Zwieten L, Wallace HM. Wood biochar increases nitrogen retention in field settings mainly through abiotic processes. Soil Biol Biochem, 2015, 90: 232-240

[7]	Bai SH, Trueman SJ, Nevenimo T, Hannet G, Bapiwai P, Poienou M, Wallace HM. Effects of shade-tree species and spacing on soil and leaf nutrient concentrations in cocoa plantations at 8 years after establishment. Agric Ecosyst Environ, 2017, 246: 134-143

[8]	Bai SH, Darby I, Nevenimo T, Hannet G, Hannet D, Poienou M, Grant E, Brooks P, Walton D, Randall B, Wallace HM. Effects of roasting on kernel peroxide value, free fatty acid, fatty acid composition and crude protein content. PLoS ONE, 2017, 12 e0184279

[9]	Bai SH, Omidvar N, Gallart M, Kamper W, Tahmasbian I, Farrar MB, Singh K, Zhou G, Muqadass B, Xu CY, Koech R, Li Y, Nguyen TTN, van Zwieten L. Combined effects of biochar and fertilizer applications on yield: a review and meta-analysis. Sci Total Environ, 2022, 808 152073

[10]	Bai SH, Farrar MB, Gallart M, Reverchon F, Tahery S, Omidvar N, Kichamu-Wachira E, Joseph SLehmann J, Joseph S. Biochar effects on nutrient leaching. Biochar for environmental management, 2024, 3London. Routledge

[11]	Baptistella JLC, de Andra SAL, Favarin JL, Mazzafera P. Urochloa in tropical agroecosystems. Front Sustain Food Syst, 2020, 4 119

[12]	Bebber DP, Richards VR. A meta-analysis of the effect of organic and mineral fertilizers on soil microbial diversity. Appl Soil Ecol, 2022, 175 104450

[13]	Becker S, Fanzo J. Population and food systems: what does the future hold?. Popul Environ, 2023, 45 20

[14]	Bernard M, Rué O, Mariadassou M, Pascal G. Frogs: a powerful tool to analyse the diversity of fungi with special management of internal transcribed spacers. Brief Bioinform, 2021,

[15]	Bozhanska T, Petkova M, Bozhanski B, Iliev M. Crude protein yield and energy nutritional value of fodder of perennial grass mixtures. Sci Pap Ser A Agron, 2023, 66(1): 234-240

[16]	Bureau of Meteorology (BOM), Australian Government (2024) Finley weather forecast. http://www.bom.gov.au/nsw/forecasts/finley.shtml

[17]	Cassman KG, Dobermann A, Walters DT. Agroecosystems, nitrogen-use efficiency, and nitrogen management. Ambio, 2002, 31(2): 132-140

[18]	Chen Q, Qu Z, Li Z, Zhang Z, Ma G, Liu Z, Wang Y, Wu L, Fang F, Wei Z, Zhang M. Coated diammonium phosphate combined with humic acid improves soil phosphorus availability and photosynthesis and the yield of maize. Front Plant Sci, 2021, 12 759929

[19]	Chowdhury MAH, Sultana T, Rahman MA, Chowdhury T, Enyoh CE, Saha BK, Qingyue W. Nitrogen use efficiency and critical leaf N concentration of Aloe vera in urea and diammonium phosphate amended soil. Heliyon, 2020, 6(12): e05718

[20]	Dai Z, Enders A, Rodrigues JL, Hanley KL, Brookes PC, Xu J, Lehmann J. Soil fungal taxonomic and functional community composition as affected by biochar properties. Soil Biol Biochem, 2018, 126: 159-167

[21]	Darby I, Xu CY, Wallace HM, Joseph S, Pace B, Bai SH. Short-term dynamics of carbon and nitrogen using compost, compost-biochar mixture and organo-mineral biochar. Environ Sci Pollut Res, 2016, 23: 11267-11278

[22]	Department of Primary Industries (DPI) (NSW) (2021) Fertilisers for Pastures 2021. https://www.lls.nsw.gov.au/help-and-advice/growing,-grazing-and-land/pastures/fertilisers-for-pastures-guide

[23]	Dissanayake L, Farrar M, Omidvar N, Joseph S, Trubenbacher K, Hosen MH, Guo L, Liu W, Bai Y, Xu Z, Bai SH. Biochar-based fertilizer is cost effective, reduces nutrient input and improves nutrient use efficiency without decreasing yield. Glob Change Biol Bioenergy, 2026,

[24]	Escudié F, Auer L, Bernard M, Mariadassou M, Cauquil L, Vidal K, Maman S, Hernandez-Raquet G, Combes S, Pascal G. FROGS: Find, rapidly, OTUs with Galaxy solution. Bioinformatics, 2018, 34(8): 1287-1294

[25]	Fang H, Liu K, Li D, Peng X, Zhang W, Zhou H. Long-term effects of inorganic fertilizers and organic manures on the structure of a paddy soil. Soil and Tillage Res, 2021, 213: 105137

[26]	Farrar MB, Wallace HM, Xu CY, Nguyen TTN, Tavakkoli E, Joseph S, Bai SH. Short-term effects of organo-mineral enriched biochar fertiliser on ginger yield and nutrient cycling. J Soils Sediments, 2019, 19: 668-682

[27]	Farrar MB, Wallace HM, Xu C-Y, Joseph S, Dunn PK, Nguyen TTN, Bai SH. Biochar co-applied with organic amendments increased soil-plant potassium and root biomass but not crop yield. J Soils Sediments, 2021, 21: 784-798

[28]	Farrar MB, Wallace HM, Xu C-Y, Joseph S, Nguyen TTN, Dunn PK, Bai SH. Biochar compound fertilisers increase plant potassium uptake 2 years after application without additional organic fertiliser. Environ Sci Pollut Res Int, 2022, 29: 7170-7184

[29]	Fierer N, Jackson RB. The diversity and biogeography of soil bacterial communities. Proc Natl Acad Sci U S A, 2006, 103(3): 626-631

[30]	Fierer N, Lauber CL, Ramirez KS, Zaneveld J, Bradford MA, Knight R. Comparative metagenomic, phylogenetic and physiological analyses of soil microbial communities across nitrogen gradients. ISME J, 2012, 6: 1007-1017

[31]	Fišarová L, Berchová K, Lukáč M, Beesley L, Vosátka M, Hausenblas M, Trakal L. Microgranular biochar improves soil fertility and mycorrhization in crop systems. Soil Use Manage, 2024, 40(2): e13068

[32]	Goldan E, Nedeff V, Barsan N. Assessment of manure compost used as soil amendment—a review. Proc, 2023, 11(4): 1167

[33]	Govil S, Long NVD, Escribà-Gelonch M, Hessel V. Controlled-release fertiliser: recent developments and perspectives. Ind Crops Prod, 2024, 219 119160

[34]	Govindasamy P, Muthusamy SK, Bagavathiannan M, Mowrer J, Jagannadham PTK, Maity A, Halli HM, Gk S, Vadivel R, Tk D. Nitrogen use efficiency—a key to enhance crop productivity under a changing climate. Front Plant Sci, 2023, 14 1121073

[35]	Hassan N, Solaiman AHM, Arefin A, Islam R, Hayder S. Efficacy of vermicompost and biochar on the growth and yield of green cabbage. Asian-Australas J Biosci Biotechnol, 2021, 6(2): 68-74

[36]	Hewitt S, Ghogare R, Troxel W, Tenic E, Isaac D, Dhingra A. Metatranscriptomic analysis of tomato rhizospheres reveals insight into plant-microbiome molecular response to biochar-amended organic soil. Front Anal Sci, 2023, 3 1205583

[37]	Horváth J, Tóth Z, Mikó E. The analysis of production and culling rate with regard to the profitability in a dairy herd. Adv Res Life Sci, 2017, 1: 48-52

[38]	Huang J, Hartemink AE. Soil and environmental issues in sandy soils. Earth Sci Rev, 2020, 208 103295

[39]	Huang S, Yu C, Fu G, Sun W, Li S, Han F, Xiao J. Effects of short-term nitrogen addition on soil fungal community increase with nitrogen addition rate in an alpine steppe at the source of brahmaputra. Microorganisms, 2023, 11(8): 1880

[40]	Ibell PT, Xu Z, Blumfield TJ. The influence of weed control on foliar δ¹⁵N, δ¹³C and tree growth in an 8-year-old exotic pine plantation of subtropical Australia. Plant Soil, 2013, 369: 199-217

[41]	Imran S, Salim SV, Adam E. Optimization the use of production factors and rice farming income. J Jambura Agribus J, 2023, 4(2): 48-58

[42]	Isbell RF. The Australian soil classification, 2016, 3rd edClayton. CSIRO Publishing

[43]	Jing F, Sun Y, Liu Y, Wan Z, Chen J, Tsang DC. Interactions between biochar and clay minerals in changing biochar carbon stability. Sci Total Environ, 2022, 809 151124

[44]	Joseph S, Graber ER, Chia C, Munroe P, Donne S, Thomas T, Nielsen S, Marjo C, Rutlidge H, Pan G-X. Shifting paradigms: development of high-efficiency biochar fertilizers based on nano-structures and soluble components. Carbon Manag, 2013, 4(3): 323-343

[45]	Joseph S, Xu CY, Wallace HM, Farrar M, Nguyen TN, Bai SH, Solaiman Z. Biochar production from agricultural and forestry wastes and microbial interactions. Current developments in biotechnology and bioengineering: solid waste management, 2017, Massachusetts. Elsevier: 443-473

[46]	Karer J, Wimmer B, Zehetner F, Kloss S, Soja G. Biochar application to temperate soils: effects on nutrient uptake and crop yield under field conditions. Agric Food Sci, 2013, 22(4): 390-403

[47]	Joseph S, Cowie AL, Van Zwieten L, Bolan N, Budai A, Buss W, Cayuela ML, Graber ER, Ippolito JA, Kuzyakov Y. How biochar works, and when it doesn't: a review of mechanisms controlling soil and plant responses to biochar. GCB Bioenergy, 2021, 13: 1731-1764

[48]	Joseph S, Taylor P (2024) A farmer’s guide to the production, use, and application of biochar. ANZ Biochar Industry Group (ANZBIG). https://anzbig.org/farmers-guide-2024/

[49]	Kraut-Cohen J, Zolti A, Rotbart N, et al. . Short- and long- term effects of continuous compost amendment on soil microbiome community. Comput Structural Biotechnol J, 2023, 21: 3280-3292

[50]	Lazcano C, Gómez-Brandón M, Revilla P, Domínguez J. Short-term effects of organic and inorganic fertilizers on soil microbial community structure and function: a field study with sweet corn. Biol Fertil Soils, 2013, 49: 723-733

[51]	Lehmann J, Joseph S. Biochar for environmental management: science, technology and implementation, 2024, 3rd edLondon. Taylor & Francis

[52]	Lehmann J, Bossio DA, Kögel-Knabner I, Rillig MC. The concept and future prospects of soil health. Nat Rev Earth Environ, 2020, 1(10): 544-553

[53]	Li Y, Li Y, Chang SX, Yang Y, Fu S, Jiang P, Luo Y, Yang M, Chen Z, Hu S. Biochar reduces soil heterotrophic respiration in a subtropical plantation through increasing soil organic carbon recalcitrancy and decreasing carbon-degrading microbial activity. Soil Biol Biochem, 2018, 122: 173-185

[54]	Li X, Wang T, Chang SX, Jiang X, Song Y. Biochar increases soil microbial biomass but has variable effects on microbial diversity: a meta-analysis. Sci Total Environ, 2020, 749 141593

[55]	Lin YH, Lin YZ, Lin YH. Preliminary design for establishing compost maturity by using the spectral characteristics of five organic fertilizers. Sci Rep, 2022, 12(1): 15721

[56]	Ma X, Zhou B, Budai A, Jeng A, Hao X, Wei D, Zhang Y, Rasse D. Study of biochar properties by scanning electron microscope–energy dispersive X-ray spectroscopy (SEM-EDX). Commun Soil Sci Plant Anal, 2016, 47(5): 593-601

[57]	Mahala DM, Maheshwari HS, Yadav RK, Prabina BJ, Bharti A, Reddy KK, Kumawat C, Ramesh A, et al. Sharma SK, et al. . Microbial transformation of nutrients in soil: an overview. Rhizosphere microbes: soil and plant functions, 2020, Berlin. Springer: 175-211

[58]	Moir JL, Cameron KC, Di HJ. Effects of the nitrification inhibitor dicyandiamide on soil mineral N, pasture yield, nutrient uptake and pasture quality in a grazed pasture system. Soil Use Manage, 2007, 23(2): 111-120

[59]	Mückschel F, Selzer T, Hauschild M, Santner J. Enhancing crop P uptake and reducing fertilizer P loss by Si-P co-fertilization?. Plant Soil, 2025,

[60]	Neto AP, Favarin JL, Hammond JP, Tezotto T, Couto HT. Analysis of phosphorus use efficiency traits in Coffea genotypes reveals Coffea arabica and Coffea canephora have contrasting phosphorus uptake and utilization efficiencies. Front Plant Sci, 2016, 7 408

[61]	Nguyen TTN, Wallace HM, Xu C-Y, Xu Z, Farrar MB, Joseph S, Van Zwieten L, Bai SH. Short-term effects of organo-mineral biochar and organic fertilisers on nitrogen cycling, plant photosynthesis, and nitrogen use efficiency. J Soils Sediments, 2017, 17: 2763-2774

[62]	Nguyen TTN, Xu C-Y, Tahmasbian I, Che R, Xu Z, Zhou X, Wallace HM, Bai SH. Effects of biochar on soil available inorganic nitrogen: a review and meta-analysis. Geoderma, 2017, 288: 79-96

[63]	Nguyen TTN, Wallace HM, Xu C-Y, Zwieten LV, Weng ZH, Xu Z, Che R, Tahmasbian I, Hu H-W, Bai SH. The effects of short term, long term and reapplication of biochar on soil bacteria. Sci Total Environ, 2018, 636: 142-151

[64]

Omidvar N, Joseph S, Dissanayake L, Farrar MB, Reverchon F, Burnett R, Rezaei Rashti M, Amarasinghe A, Tahery S, Xu Z, Timms W, Elliott B, Liu H, Bai SH. Combination of biochar-based fertilisers and reactive barriers improved soil carbon storage, soil moisture retention, and crop yield in short term. GCB Bioenergy, 2025,

[65]

Omidvar N, Hosen MD, Farrar MB, Dissanayake L, Burns GL, Das S, Chaki AK, Neogi MG, Rahman MW, Nguyen TTN, Rashti R, Elliott B, Bai SH. Co-application of biochar and organic matter with synthetic fertilisers improves nitrogen use efficiency, rice yield and benefit-cost ratio: a meta-analysis. GCB Bioenergy, 2026,

[66]	Palansooriya KN, Wong JTF, Hashimoto Y, Huang L, Rinklebe J, Chang SX, Bolan N, Wang H, Ok YS. Response of microbial communities to biochar-amended soils: a critical review. Biochar, 2019, 1: 3-22

[67]	Pandit NR, Mulder J, Hale SE, Zimmerman AR, Pandit BH, Cornelissen G. Multi-Year Double Cropping Biochar Field Trials in Nepal: Finding the Optimal Biochar Dose Through Agronomic Trials and Cost- Benefit Analysis. Sci Total Environ, 2018, 637: 1333-1341

[68]	Patel MR, Panwar NL. Evaluating the agronomic and economic viability of biochar in sustainable crop production. Biomass Bioenerg, 2024, 188 107328

[69]	Põlme S, Abarenkov K, Nilsson HR, Lindahl BD, Engelbrecht Clemmensen K, Kauserud H, Nguyen N, Kjøller R, et al. . FungalTraits: a user-friendly traits database of fungi and fungus-like stramenopiles. Fungal Divers, 2020, 105: 1-16

[70]	Rayment GE, Lyons DJ. Soil chemical methods: australasia, 2011, Clayton. CSIRO Publishing

[71]	Rickson RJ, Deeks LK, Graves AR, Harris JA, Kibblewhite MG, Sakrabani R. Input constraints to food production: the impact of soil degradation. Food Secur, 2015, 7: 351-364

[72]	Sande TJ, Tindwa HJ, Alovisi AMT, Shitindi MJ, Semoka JM. Enhancing sustainable crop production through integrated nutrient management: a focus on vermicompost, bio-enriched rock phosphate, and inorganic fertilisers–a systematic review. Front Agron, 2024, 6 1422876

[73]	Seghouani M, Bravin MN, Mollier A. Crop response to nitrogen-phosphorus colimitation: theory, experimental evidences, mechanisms, and models. A review. Agron Sustain Dev, 2024, 44(1): 3

[74]	Serrano J, Shahidian S, Moral FJ. Crude protein as an indicator of pasture availability and quality: a validation of two complementary sensors. Agronomy, 2024, 14(10): 2310

[75]	Shen W, Ni Y, Gao N, Bian B, Zheng S, Lin X, Chu H. Bacterial community composition is shaped by soil secondary salinization and acidification brought on by high nitrogen fertilization rates. Appl Soil Ecol, 2016, 108: 76-83

[76]	Sheng Y, Zhu L. Biochar alters microbial community and carbon sequestration potential across different soil pH. Sci Total Environ, 2018, 622–623: 1391-1399

[77]	Singh B. Are nitrogen fertilizers deleterious to soil health?. Agron, 2018, 8(4): 48

[78]	Singh P, Benbi DK, Verma G. Nutrient management impacts on nutrient use efficiency and energy, carbon, and net ecosystem economic budget of a rice–wheat cropping system in Northwestern India. J Soil Sci Plant Nutr, 2021, 21: 559-577

[79]	Skorupka M, Nosalewicz A. Ammonia volatilization from fertilizer urea—a new challenge for agriculture and industry in view of growing global demand for food and energy crops. Agriculture, 2021, 11(9): 822

[80]	Smith J, Fukai S, Bell M. Soil and fertiliser nitrogen performance indicators for irrigated cotton in Australia. Soil Res, 2022, 61(4): 329-344

[81]	Sorensen RB, Lamb MC. Return on investment from biochar application. Crop Forage Turfgrass Manag, 2018, 4(1): 1-6

[82]	Stamate N, Ranta O, Ghețe A, Marian O, Bogdan C, Irimie AM. Equipment and systems for the application of liquid fertilizers in field crops—news and perspectives. Agricultura, 2024,

[83]	Tian J, Wang J, Dippold M, Gao Y, Blagodatskaya E, Kuzyakov Y. Biochar affects soil organic matter cycling and microbial functions but does not alter microbial community structure in a paddy soil. Sci Total Environ, 2016, 556: 89-97

[84]	Tisserant A, Cherubini F. Potentials, limitations, co-benefits, and trade-offs of biochar applications to soils for climate change mitigation. Land, 2019, 8(12): 179

[85]	Tong Y, Dong Q, Yu Y, Cao Q, Yang X, Liu W, Yang Z, Zhang X, Liu Y, Zhang C. Nitrogen application increases the productivity of perennial alpine cultivated grassland by improving soil physicochemical properties and microbial community characteristics. Plant Soil, 2024, 505: 559-579

[86]	Touhami D, McDowell RW, Condron LM, Bouray M. Nitrogen fertilization effects on soil phosphorus dynamics under a grass-pasture system. Nutr Cycl Agroecosyst, 2022, 124: 227-246

[87]	Trubenbacher K, Hosseini Bai S, Dissanayake L, Omidvar N, Joseph S, Farrar MB. Effects of biochar-based fertilizer on root zeta potential, nutrient leaching and yield in an intensive protected cropping system. Land, 2025, 14(10): 2036

[88]	Wang Y, Zhang W, Shang J, Shen C, Joseph SD. Chemical aging changed aggregation kinetics and transport of biochar colloids. Environ Sci Technol, 2019, 53(14): 8136-8146

[89]	Wang M, Wang L, Li Q, Liu H, Lin Y, Wang L. Nitrogen fertilizer driven bacterial community structure in a semi-arid region of Northeast China. Sustainability, 2021, 13(21): 11967

[90]	Wong JTF, Chen X, Deng W, Chai Y, Ng CWW, Wong MH. Effects of biochar on bacterial communities in a newly established landfill cover topsoil. J Environ Manage, 2019, 236: 667-673

[91]	Xiong Q, Wang S, Lu X, Xu Y, Zhang L, Chen X, Xu G, Tian D, Zhang L, Jing J, Ye X. The effective combination of humic acid phosphate fertilizer regulating the form transformation of phosphorus and the chemical and microbial mechanism of its phosphorus availability. Agronomy, 2023, 13(6): 1581

[92]	Xu Y, Seshadri B, Sarkar B, Rumpel C, Sparks D, Bolan NSGarcia C, Nannipieri P, Hernandez T. Chapter 6 - Microbial control of soil carbon turnover. The future of soil carbon, 2018, London. Academic Press: 165-194

[93]	Yang G, Ji H, Liu H, Zhang Y, Chen L, Zheng J, Guo Z, Sheng J. Assessment of productivity, nutrient uptake and economic benefits of rice under different nitrogen management strategies. PeerJ, 2020, 8 e9596

[94]	Yang Y, Chen X, Liu L, Li T, Dou Y, Qiao J, Wang Y, An S, Chang SX. Nitrogen fertilization weakens the linkage between soil carbon and microbial diversity: a global meta-analysis. Glob Change Biol, 2022, 28(21): 6446-6461

[95]	Yang X, Bol R, Xia L, Xu C, Yuan N, Xu X, Wu W, Meng F. Integrated farming optimization ensures high-yield crop production with decreased nitrogen leaching and improved soil fertility: the findings from a 12-year experimental study. Field Crops Res, 2024, 318 109572

[96]	Zeng J, Liu X, Song L, Lin X, Zhang H, Shen C, Chu H. Nitrogen fertilization directly affects soil bacterial diversity and indirectly affects bacterial community composition. Soil Biol Biochem, 2016, 92: 41-49

[97]	Zeng W, Wang Z, Chen X, Yao X, Ma Z, Wang W. Nitrogen deficiency accelerates soil organic carbon decomposition in temperate degraded grasslands. Sci Total Environ, 2023, 881 163424

[98]	Zhang L, Jing Y, Xiang Y, Zhang R, Lu H. Responses of soil microbial community structure changes and activities to biochar addition: a meta-analysis. Sci Total Environ, 2018, 643: 926-935

[99]	Zhang X, Feng X, Chai N, Kuzyakov Y, Zhang F, Li FM. Biochar effects on crop yield variability. Field Crops Res, 2024, 316 109518

[100]

Zheng D, Lyu Y, Ros GH, de Vries W, Rengel Z, Shen J. Heterogeneous co-supplies of phosphorus, sulfur and carbon enhance phosphorus availability by improving rhizosphere processes in a calcareous soil. Plant Soil, 2024, 502(1–2): 195-210