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Rosa-Martínez E, Bovy A, Plazas M, Tikunov Y, Prohens J, et al. 2023. Genetics and breeding of phenolic content in tomato, eggplant and pepper fruits. Frontiers in Plant Science 14:1135237

Pradhan P, Naresh P, Barik S, Acharya GC, Bastia R, et al. 2023. Breeding for root-knot nematode resistance in fruiting Solanaceous vegetable crops: a review. Euphytica 219:71

Bennett AJ, Bending GD, Chandler D, Hilton S, Mills P. 2012. Meeting the demand for crop production: the challenge of yield decline in crops grown in short rotations. Biological Reviews 87:52−71

Ma HK, Pineda A, van der Wurff AWG, Bezemer TM. 2018. Carry-over effects of soil inoculation on plant growth and health under sequential exposure to soil-borne diseases. Plant and Soil 433:257−270

Ku Y, Li W, Mei X, Yang X, Cao C, et al. 2022. Biological control of melon continuous cropping obstacles: weakening the negative effects of the vicious cycle in continuous cropping soil. Microbiology Spectrum 10:e01776-22

Li Y, Chi J, Ao J, Gao X, Liu X, et al. 2021. Effects of different continuous cropping years on bacterial community and diversity of cucumber rhizosphere soil in solar-greenhouse. Current Microbiology 78:2380−2390

Liao J, Xia P. 2024. Continuous cropping obstacles of medicinal plants: focus on the plant-soil-microbe interaction system in the rhizosphere. Scientia Horticulturae 328:112927

Tan G, Liu Y, Peng S, Yin H, Meng D, et al. 2021. Soil potentials to resist continuous cropping obstacle: three field cases. Environmental Research 200:111319

Zhao X, Elcin E, He L, Vithanage M, Zhang X, et al. 2024. Using biochar for the treatment of continuous cropping obstacle of herbal remedies: a review. Applied Soil Ecology 193:105127

Aly A, Piscitelli L, Laarif Y, Rouifi A, Mondelli D, et al. 2024. Compost tea supplied by partial root-zone drying irrigation affected growth and productivity of eggplants and cucumbers grown in succession. Biological Agriculture & Horticulture 40:12−23

Chen W, Guo X, Guo Q, Tan X, Wang Z. 2021. Long-term chili monoculture alters environmental variables affecting the dominant microbial community in rhizosphere soil. Frontiers in Microbiology 12:681953

Cheng F, Ali M, Liu C, Deng R, Cheng Z. 2020. Garlic allelochemical diallyl disulfide alleviates autotoxicity in the root exudates caused by long-term continuous cropping of tomato. Journal of Agricultural and Food Chemistry 68:11684−11693

Wang Y, Shi M, Zhang R, Zhang W, Liu Y, et al. 2023. Legume-potato rotation affects soil physicochemical properties, enzyme activity, and rhizosphere metabolism in continuous potato cropping. Chemical and Biological Technologies in Agriculture 10:132

Mao T, Jiang X. 2021. Changes in microbial community and enzyme activity in soil under continuous pepper cropping in response to Trichoderma hamatum MHT1134 application. Scientific Reports 11:21585

Ma L, Ma S, Chen G, Lu X, Chai Q, et al. 2023. Mechanisms and mitigation strategies for the occurrence of continuous cropping obstacles of Legumes in China. Agronomy 14:104

Jokela D, Nair A. 2016. Effects of reduced tillage and fertilizer application method on plant growth, yield, and soil health in organic bell pepper production. Soil and Tillage Research 163:243−254

Ma HJ, Lin L, Chen ZB, Xu SG, Li Y, et al. 2023. Biochar preparation and its effects with reduced compound fertilizer on nutrients, phenolic acid and fungal community in tobacco rhizosphere soil. Materials Express 13:1888−1898

Zhao L, Zhao Y, Nan H, Yang F, Qiu H, et al. 2020. Suppressed formation of polycyclic aromatic hydrocarbons (PAHs) during pyrolytic production of Fe-enriched composite biochar. Journal of Hazardous Materials 382:121033

Chen X, Zhang D, Li X, Li X, Lou J, et al. 2022. Effect of vegetable residues incorporation on soil fertility, rhizosphere microbial community structure, and plant growth of continuously cropped cucumber in a solar greenhouse. Annals of Microbiology 72:32

Cui J, Zhang E, Zhang X, Wang Q, Liu Q. 2022. Effects of 2, 4-di-tert-butylphenol at different concentrations on soil functionality and microbial community structure in the Lanzhou lily rhizosphere. Applied Soil Ecology 172:104367

Kaur J, Singh JP. 2014. Long-term effects of continuous cropping and different nutrient management practices on the distribution of organic nitrogen in soil under rice-wheat system. Plant, Soil and Environment 60:63−68

Manici LM, Kelderer M, Franke-Whittle IH, Rühmer T, Baab G, et al. 2013. Relationship between root-endophytic microbial communities and replant disease in specialized apple growing areas in Europe. Applied Soil Ecology 72:207−214

Wang Y, Ma X, Saleem M, Yang Y, Zhang Q. 2022. Effects of corn stalk biochar and pyrolysis temperature on wheat seedlings growth and soil properties stressed by herbicide sulfentrazone. Environmental Technology & Innovation 25:102208

Xing Y, Zhang P, Zhang W, Yu C, Luo Z. 2024. Continuous cropping of potato changed the metabolic pathway of root exudates to drive rhizosphere microflora. Frontiers in Microbiology 14:1318586

Barik S, Reddy AC, Ponnam N, Kumari M, Acharya GC, et al. 2020. Breeding for bacterial wilt resistance in eggplant (Solanum melongena L.): progress and prospects. Crop Protection 137:105270

Ding M, Dai H, He Y, Liang T, Zhai Z, et al. 2024. Continuous cropping system altered soil microbial communities and nutrient cycles. Frontiers in Microbiology 15:1374550

Ashworth AJ, Owens PR, Allen FL. 2020. Long-term cropping systems management influences soil strength and nutrient cycling. Geoderma 361:114062

Hati KM, Swarup A, Dwivedi AK, Misra AK, Bandyopadhyay KK. 2007. Changes in soil physical properties and organic carbon status at the topsoil horizon of a vertisol of central India after 28 years of continuous cropping, fertilization and manuring. Agriculture, Ecosystems & Environment 119:127−134

Almajmaie A, Hardie M, Acuna T, Birch C. 2017. Evaluation of methods for determining soil aggregate stability. Soil and Tillage Research 167:39−45

Amézketa E. 1999. Soil aggregate stability: a review. Journal of Sustainable Agriculture 14:83−151

Pervaiz ZH, Iqbal J, Zhang Q, Chen D, Wei H, et al. 2020. Continuous cropping alters multiple biotic and abiotic indicators of soil health. Soil Systems 4:59

Huang LF, Song LX, Xia XJ, Mao WH, Shi K, et al. 2013. Plant-soil feedbacks and soil sickness: from mechanisms to application in agriculture. Journal of Chemical Ecology 39:232−242

Kumbar S, Narayanankutty C, Sainamole KP, Sreelatha U, Barik S. 2021. Evaluation of eggplant rootstocks for grafting eggplant to improve fruit yield and control bacterial wilt disease. European Journal of Plant Pathology 161:73−90

Ma H, Li J, Luo A, Lv H, Ren Z, et al. 2023. Vanillin, a newly discovered autotoxic substance in long-term potato continuous cropping soil, inhibits plant growth by decreasing the root auxin content and reducing adventitious root numbers. Journal of Agricultural and Food Chemistry 71:16993−17004

Rial C, Gómez E, Varela RM, Molinillo JMG, Macías FA. 2018. Ecological relevance of the major allelochemicals in Lycopersicon esculentum roots and exudates. Journal of Agricultural and Food Chemistry 66:4638−4644

Rahaman F, Shukor Juraimi A, Rafii MY, Uddin K, Hassan L, et al. 2022. Allelopathic potential in rice-a biochemical tool for plant defence against weeds. Frontiers in Plant Science 13:1072723

Terán-Figueroa Y, de Loera D, Toxqui-Terán A, Montero-Morán G, Saavedra-Leos MZ. 2022. Bromatological analysis and characterization of phenolics in snow mountain garlic. Molecules 27:3712

Zeeshan Ul Haq M, Yu J, Yao G, Yang H, Iqbal HA, et al. 2023. A systematic review on the continuous cropping obstacles and control strategies in medicinal plants. International Journal of Molecular Sciences 24:12470

Wang L, Liu S, Tian G, Pan Y, Wang H, et al. 2025. Impacts of continuous potato cropping on soil microbial assembly processes and spread of potato common scab. Applied Soil Ecology 206:105805

Colak N, Kurt-Celebi A, Gruz J, Strnad M, Hayirlioglu-Ayaz S, et al. 2022. The phenolics and antioxidant properties of black and purple versus white eggplant cultivars. Molecules 27:2410

Xiao Z, Lu C, Wu Z, Li X, Ding K, et al. 2024. Continuous cropping disorders of eggplants (Solanum melongena L.) and tomatoes (Solanum lycopersicum L.) in suburban agriculture: microbial structure and assembly processes. Science of The Total Environment 909:168558

Gao H, Tian G, Khashi u Rahman M, Wu F. 2022. Cover crop species composition alters the soil bacterial community in a continuous pepper cropping system. Frontiers in Microbiology 12:789034

Sánchez-Mata MC, Yokoyama WE, Hong YJ, Prohens J. 2010. α-Solasonine and α-solamargine contents of gboma (Solanum macrocarpon L.) and scarlet (Solanum aethiopicum L.) eggplants. Journal of Agricultural and Food Chemistry 58:5502−5508

Bao L, Liu Y, Ding Y, Shang J, Wei Y, et al. 2022. Interactions between phenolic acids and microorganisms in rhizospheric soil from continuous cropping of Panax notoginseng. Frontiers in Microbiology 13:791603

Fan Y, Liu J, Liu Z, Hu X, Yu Z, et al. 2022. Chitin amendments eliminate the negative impacts of continuous cropping obstacles on soil properties and microbial assemblage. Frontiers in Plant Science 13:1067618

Gu S, Xiong X, Tan L, Deng Y, Du X, et al. 2022. Soil microbial community assembly and stability are associated with potato (Solanum tuberosum L.) fitness under continuous cropping regime. Frontiers in Plant Science 13:1000045

Liu S, Wang Z, Niu J, Dang K, Zhang S, et al. 2021. Changes in physicochemical properties, enzymatic activities, and the microbial community of soil significantly influence the continuous cropping of Panax quinquefolius L. (American ginseng). Plant and Soil 463:427−446

Yang T, Zhai D, Ding X, Guo Z, Zhao Y. 2023. Shifts in soil microbial diversity and functions during continuous cropping of strawberry. Land Degradation & Development 34:4810−4820

Zhang Y, Zheng Y, Xia P, Xun L, Liang Z. 2019. Impact of continuous Panax notoginseng plantation on soil microbial and biochemical properties. Scientific Reports 9:13205

Huang Y, Xiao X, Huang H, Jing J, Zhao H, et al. 2018. Contrasting beneficial and pathogenic microbial communities across consecutive cropping fields of greenhouse strawberry. Applied Microbiology and Biotechnology 102:5717−5729

Liu L, Sun C, Liu S, Chai R, Huang W, et al. 2015. Bioorganic fertilizer enhances soil suppressive capacity against bacterial wilt of tomato. PLoS One 10:e0121304

Liu W, Wang Q, Wang B, Wang X, Franks AE, et al. 2015. Changes in the abundance and structure of bacterial communities under long-term fertilization treatments in a peanut monocropping system. Plant and Soil 395:415−427

Cen Z, Zheng Y, Guo Y, Yang S, Dong Y. 2023. Nitrogen fertilization in a faba bean-wheat intercropping system can alleviate the autotoxic effects in faba bean. Plants 12:1232

Huang S, Yu J, Hou D, Yue H, Zhang D, et al. 2023. Response of soil microbial community diversity to continuous cucumber cropping in facilities along the Yellow River irrigation area. PLoS One 18:e0289772

Su L, Li H, Wang J, Gao W, Shu X, et al. 2023. Composition, function and succession of bacterial communities in the tomato rhizosphere during continuous cropping. Biology and Fertility of Soils 59:723−732

Chen J, Du Y, Zhu W, Pang X, Wang Z. 2022. Effects of organic materials on soil bacterial community structure in long-term continuous cropping of tomato in greenhouse. Open Life Sciences 17:381−392

Ding Y, Huang X, Li Y, Liu H, Zhang Q, et al. 2021. Nitrate leaching losses mitigated with intercropping of deep-rooted and shallow-rooted plants. Journal of Soils and Sediments 21:364−375

Ghani MI, Ali A, Atif MJ, Ali M, Amin B, et al. 2022. Arbuscular mycorrhizal fungi and dry raw garlic stalk amendment alleviate continuous monocropping growth and photosynthetic declines in eggplant by bolstering its antioxidant system and accumulation of osmolytes and secondary metabolites. Frontiers in Plant Science 13:849521

Liu F, Li X, Hu H, Li J, Du G, et al. 2023. Hemp (Cannabis sativa L.) interruption cultivation evidently decreases the anthracnose in the succeeding crop chilli (Capsicum annuum L.). Agronomy 13:1228

Qin S, Yeboah S, Wang D, Zhang J. 2016. Effects of ridge‐furrow and plastic mulching planting patterns on microflora and potato tuber yield in continuous cropping soil. Soil Use and Management 32:465−473

Zheng X, Zhu Y, Wang Z, Zhang H, Chen M, et al. 2020. Effects of a novel bio-organic fertilizer on the composition of rhizobacterial communities and bacterial wilt outbreak in a continuously mono-cropped tomato field. Applied Soil Ecology 156:103717

Zhong S, Zeng HC. 2019. Effect of peanut (Arachis hypogaea L.)/cowpea (Vigna unquiculata L.) intercropping combined with organic mature application on soil microfauna. Geoderma 354:113863

Wang T, Xu J, Chen J, Liu P, Hou X, et al. 2024. Progress in microbial fertilizer regulation of crop growth and soil remediation research. Plants 13:346

Galindo FS, Pagliari PH, da Silva EC, de Lima BH, Fernandes GC, et al. 2024. Impact of nitrogen fertilizer sustainability on corn crop yield: the role of beneficial microbial inoculation interactions. BMC Plant Biology 24:268

Xiong W, Li R, Guo S, Karlsson I, Jiao Z, et al. 2019. Microbial amendments alter protist communities within the soil microbiome. Soil Biology and Biochemistry 135:379−382

Huang X, Zhao J, Zhou X, Zhang J, Cai Z. 2019. Differential responses of soil bacterial community and functional diversity to reductive soil disinfestation and chemical soil disinfestation. Geoderma 348:124−134

Liu X, Feng Z, Zhou Y, Zhu H, Yao Q. 2020. Plant species-dependent effects of liming and plant residue incorporation on soil bacterial community and activity in an acidic orchard soil. Applied Sciences 10:5681

Liu M, Linna C, Ma S, Ma Q, Guo J, et al. 2022. Effects of biochar with inorganic and organic fertilizers on agronomic traits and nutrient absorption of soybean and fertility and microbes in purple soil. Frontiers in Plant Science 13:871021

Singh HP, Batish DR, Kohli RK. 1999. Autotoxicity: concept, organisms, and ecological significance. Critical Reviews in Plant Sciences 18:757−772

Schneider F, Don A, Hennings I, Schmittmann O, Seidel SJ. 2017. The effect of deep tillage on crop yield–What do we really know? Soil and Tillage Research 174:193−204

Chen Q, Lan P, Wu M, Lu M, Pan B, et al. 2022. Biochar mitigates allelopathy through regulating allelochemical generation from plants and accumulation in soil. Carbon Research 1:6

Zheng X, Wang Z, Zhu Y, Wang J, Liu B. 2020. Effects of a microbial restoration substrate on plant growth and rhizosphere bacterial community in a continuous tomato cropping greenhouse. Scientific Reports 10:13729

Wang C, Zheng N, Wan S, Wang J. 2021. Assessment of the modes of occurrence of trace elements in agricultural crop residues and their enrichments and bioavailability in bio-chars. Biomass Conversion and Biorefinery 11:2065−2077

Jiang M, He L, Niazi NK, Wang H, Gustave W, et al. 2023. Nanobiochar for the remediation of contaminated soil and water: challenges and opportunities. Biochar 5:2

Alghamdi AG, Aljohani BH, Aly AA. 2021. Impacts of olive waste-derived biochar on hydro-physical properties of sandy soil. Sustainability 13:5493

Ndede EO, Kurebito S, Idowu O, Tokunari T, Jindo K. 2022. The potential of biochar to enhance the water retention properties of sandy agricultural soils. Agronomy 12:311

Jaiswal AK, Alkan N, Elad Y, Sela N, Philosoph AM, et al. 2020. Molecular insights into biochar-mediated plant growth promotion and systemic resistance in tomato against Fusarium crown and root rot disease. Scientific Reports 10:13934

Ge S, Gao J, Chang D, He T, Cai H, et al. 2023. Biochar contributes to resistance against root rot disease by stimulating soil polyphenol oxidase. Biochar 5:55

de Medeiros EV, Lima NT, de Sousa Lima JR, Pinto KMS, da Costa DP, et al. 2022. Biochar from different sources against tomato bacterial wilt disease caused by Ralstonia solanacearum. Journal of Soil Science and Plant Nutrition 22:540−548

Xie H, Zhou X, Zhang Y. 2024. Effects of biochar under different preparation conditions on the growth of capsicum. Sustainability 16:6869

Arshad U, Azeem F, Mustafa G, Bakhsh A, Toktay H, et al. 2021. Combined application of biochar and biocontrol agents enhances plant growth and activates resistance against Meloidogyne incognita in tomato. Gesunde Pflanzen 73:591−601

Lin CC, Liu YT, Chang PH, Hsieh YC, Tzou YM. 2023. Inhibition of continuous cropping obstacle of celery by chemically modified biochar: an efficient approach to decrease bioavailability of phenolic allelochemicals. Journal of Environmental Management 348:119316

Luigi M, Manglli A, Dragone I, Antonelli MG, Contarini M, et al. 2022. Effects of biochar on the growth and development of tomato seedlings and on the response of tomato plants to the infection of systemic viral agents. Frontiers in Microbiology 13:862075

Calcan SI, Pârvulescu OC, Ion VA, Răducanu CE, Bădulescu L, et al. 2022. Effects of biochar on soil properties and tomato growth. Agronomy 12:1824

Tao R, Zhang Y, Yang J, Yang T, White JC, et al. 2023. Biochar nanoparticles alleviate salt stress in tomato (Solanum lycopersicum) seedlings. Environmental Science: Nano 10:1800−1811

Guo L, Bornø ML, Niu W, Liu, F. 2021. Biochar amendment improves shoot biomass of tomato seedlings and sustains water relations and leaf gas exchange rates under different irrigation and nitrogen regimes. Agricultural Water Management 245:106580

Ebrahimi M, Souri MK, Mousavi A, Sahebani N. 2021. Biochar and vermicompost improve growth and physiological traits of eggplant (Solanum melongena L.) under deficit irrigation. Chemical and Biological Technologies in Agriculture 8:19

Ali Ahmad C, Akhter A, Haider MS, Abbas MT, Hashem A, et al. 2024. Demonstration of the synergistic effect of biochar and Trichoderma harzianum on the development of Ralstonia solanacearum in eggplant. Frontiers in Microbiology 15:1360703

Mawof A, Prasher S, Bayen S, Nzediegwu C. 2021. Effects of biochar and biochar-compost mix as soil amendments on soil quality and yield of potatoes irrigated with wastewater. Journal of Soil Science and Plant Nutrition 21:2600−2612

Wang H, Chen S, Liu H, Li J, Zaman QU, et al. 2023. Maize straw biochar can alleviate heavy metals stress in potato by improving soil health. South African Journal of Botany 162:391−401

Kassaye KT, Boulange J, Kurebito S, Tokunari T, Saito H, et al. 2022. The role of biochar in improving soil properties, water retention and potato yield in a Fluvisol under temperate monsoon climate. Soil Use and Management 38:1069−1083

Zhang M, Liu Y, Wei Q, Liu L, Gu X, et al. 2023. Chemical fertilizer reduction combined with biochar application ameliorates the biological property and fertilizer utilization of pod pepper. Agronomy 13:1616

Lan P, Chen Q, Lu M, Steinberg CEW, Wu M, et al. 2023. Biochar reduces generation and release of benzoic acid from soybean root. Journal of Soil Science and Plant Nutrition 23:5026−5035

Chen Y, Qiu Y, Hao X, Tong L, Li S, et al. 2023. Does biochar addition improve soil physicochemical properties, bacterial community and alfalfa growth for saline soils? Land Degradation & Development 34:3314−3328

Gujre N, Soni A, Rangan L, Tsang DCW, Mitra S. 2021. Sustainable improvement of soil health utilizing biochar and arbuscular mycorrhizal fungi: a review. Environmental Pollution 268:115549

Feng W, Wang T, Yang F, Cen R, Liao H, et al. 2023. Effects of biochar on soil evaporation and moisture content and the associated mechanisms. Environmental Sciences Europe 35:66

Huang R, Tian D, Liu J, Lv S, He X, et al. 2018. Responses of soil carbon pool and soil aggregates associated organic carbon to straw and straw-derived biochar addition in a dryland cropping mesocosm system. Agriculture, Ecosystems & Environment 265:576−586

Ahmad Bhat S, Kuriqi A, Dar MUD, Bhat O, Sammen SS, et al. 2022. Application of biochar for improving physical, chemical, and hydrological soil properties: a systematic review. Sustainability 14:11104

Molnár M, Vaszita E, Farkas É, Ujaczki É, Fekete-Kertész I, et al. 2016. Acidic sandy soil improvement with biochar—a microcosm study. Science of The Total Environment 563:855−865

Öz H. 2018. A new approach to soil solarization: addition of biochar to the effect of soil temperature and quality and yield parameters of lettuce (Lactuca sativa L. Duna). Scientia Horticulturae 228:153−161

Limwikran T, Kheoruenromne I, Suddhiprakarn A, Prakongkep N, Gilkes RJ. 2019. Most plant nutrient elements are retained by biochar in soil. Soil Systems 3:75

Suliman W, Harsh JB, Abu-Lail NI, Fortuna AM, Dallmeyer I, et al. 2017. The role of biochar porosity and surface functionality in augmenting hydrologic properties of a sandy soil. Science of The Total Environment 574:139−147

Ali AB, Elshaikh NA. 2022. Review: performance of biochar under diminish water stress in plants. Communications in Soil Science and Plant Analysis 53:1−16

Hossain MZ, Bahar MM, Sarkar B, Donne SW, Ok YS, et al. 2020. Biochar and its importance on nutrient dynamics in soil and plant. Biochar 2:379−420

Yadav V, Singh NB, Singh H, Singh A, Hussain I. 2019. Putrescine affects tomato growth and response of antioxidant defense system due to exposure to cinnamic acid. International Journal of Vegetable Science 25:259−277

Zhang Z, Chen L, Wang J, Yao J, Li J. 2018. Biochar preparation from Solidago canadensis and its alleviation of the inhibition of tomato seed germination by allelochemicals. RSC Advances 8:22370−22375

Graber ER, Meller HY, Kolton M, Cytryn E, Silber A, et al. 2010. Biochar impact on development and productivity of pepper and tomato grown in fertigated soilless media. Plant and Soil 337:481−496

Chen Z, Wang J, Wang Y, Li B, Wang M. 2021. Rapid formation of pyrogenic char (biochar) with high and low sorption capacity towards organic chemicals. Environmental Pollution 273:116472

Dong M, He L, Jiang M, Zhu Y, Wang J, et al. 2023. Biochar for the removal of emerging pollutants from aquatic systems: a review. International Journal of Environmental Research and Public Health 20:1679

Ma S, Jing F, Sohi SP, Chen J. 2019. New insights into contrasting mechanisms for PAE adsorption on millimeter, micron-and nano-scale biochar. Environmental Science and Pollution Research 26:18636−18650

Yuan Y, Bolan N, Prévoteau A, Vithanage M, Biswas JK, et al. 2017. Applications of biochar in redox-mediated reactions. Bioresource Technology 246:271−281

Ahmed MB, Zhou JL, Ngo HH, Abu Hasan Johir M, Sun L, et al. 2018. Sorption of hydrophobic organic contaminants on functionalized biochar: Protagonist role of π-π electron-donor-acceptor interactions and hydrogen bonds. Journal of Hazardous Materials 360:270−278

Ahmad M, Rajapaksha AU, Lim JE, Zhang M, Bolan N, et al. 2014. Biochar as a sorbent for contaminant management in soil and water: a review. Chemosphere 99:19−33

Dai Y, Zhang N, Xing C, Cui Q, Sun Q. 2019. The adsorption, regeneration and engineering applications of biochar for removal organic pollutants: a review. Chemosphere 223:12−27

Xu Y, Yu X, Xu B, Peng D, Guo X. 2021. Sorption of pharmaceuticals and personal care products on soil and soil components: influencing factors and mechanisms. Science of The Total Environment 753:141891

Rasul M, Cho J, Shin HS, Hur J. 2022. Biochar-induced priming effects in soil via modifying the status of soil organic matter and microflora: a review. Science of The Total Environment 805:150304

Fang G, Zhu C, Dionysiou DD, Gao J, Zhou D. 2015. Mechanism of hydroxyl radical generation from biochar suspensions: implications to diethyl phthalate degradation. Bioresource Technology 176:210−217

Chen Y, Du J, Li Y, Tang H, Yin Z, et al. 2022. Evolutions and managements of soil microbial community structure drove by continuous cropping. Frontiers in Microbiology 13:839494

Qin Y, Li G, Gao Y, Zhang L, Ok YS, et al. 2018. Persistent free radicals in carbon-based materials on transformation of refractory organic contaminants (ROCs) in water: a critical review. Water Research 137:130−143

Lai C, Zhan J, Chai Q, Wang C, Yang X, et al. 2025. Dissolved carbon in biochar: exploring its chemistry, iron complexing capability, toxicity in natural redox environment. Journal of Environmental Sciences 147:217−229

Swagathnath G, Rangabhashiyam S, Murugan S, Balasubramanian P. 2019. Influence of biochar application on growth of Oryza sativa and its associated soil microbial ecology. Biomass Conversion and Biorefinery 9:341−352

Jaiswal AK, Elad Y, Paudel I, Graber ER, Cytryn E, et al. 2017. Linking the belowground microbial composition, diversity and activity to soilborne disease suppression and growth promotion of tomato amended with biochar. Scientific Reports 7:44382

Ogundeji AO, Li Y, Liu X, Meng L, Sang P, et al. 2021. Eggplant by grafting enhanced with biochar recruits specific microbes for disease suppression of Verticillium wilt. Applied Soil Ecology 163:103912

Bhatti AA, Haq S, Bhat RA. 2017. Actinomycetes benefaction role in soil and plant health. Microbial Pathogenesis 111:458−467

Fu Y, Luo Y, Auwal M, Singh BP, Van Zwieten L, et al. 2022. Biochar accelerates soil organic carbon mineralization via rhizodeposit-activated Actinobacteria. Biology and Fertility of Soils 58:565−577

Hematimatin N, Igaz D, Aydın E, Horák J. 2024. Biochar application regulating soil inorganic nitrogen and organic carbon content in cropland in the Central Europe: a seven-year field study. Biochar 6:14

Liu X, Li Y, Ren X, Chen B, Zhang Y, et al. 2020. Long-term greenhouse cucumber production alters soil bacterial community structure. Journal of Soil Science and Plant Nutrition 20:306−321

Li H, Lou J, Chen X, Dou Y, Zhang D, et al. 2024. Effects of sweet pepper straw biochar on soil microbial communities and growth of continuously cropped cucumber. Annals of Microbiology 74:12

He X, Xie H, Gao D, Khashi u Rahman M, Zhou X, et al. 2021. Biochar and intercropping with potato-onion enhanced the growth and yield advantages of tomato by regulating the soil properties, nutrient uptake, and soil microbial community. Frontiers in Microbiology 12:695447

Jia W, Wang C, Ma C, Wang J, Sun H, et al. 2019. Mineral elements uptake and physiological response of Amaranthus mangostanus (L.) as affected by biochar. Ecotoxicology and Environmental Safety 175:58−65

Foong SY, Cheong KY, Kong SH, Yiin CL, Yek PNY, et al. 2023. Recent progress in the production and application of biochar and its composite in environmental biodegradation. Bioresource Technology 387:129592