Back Article

Ullah Z, Joseph CG, Tian ZY, Yasin M, Khan MN, et al. 2025. The production of biochar and its impact on the removal of various emerging pollutants from wastewater: a review. Toxics 13(12):1079

Amdeha E. 2024. Biochar-based nanocomposites for industrial wastewater treatment via adsorption and photocatalytic degradation and the parameters affecting these processes. Biomass Conversion and Biorefinery 14(19):23293−23318

Noreen S, Abd-Elsalam KA. 2021. Biochar-based nanocomposites: a sustainable tool in wastewater bioremediation. In Aquananotechnology: Applications of Nanomaterials for Water Purification. eds. Abd-Elsalam KA, Zahid M. Amsterdam: Elsevier. pp. 185−200 doi: 10.1016/b978-0-12-821141-0.00023-9

Hayder G, Naim RM. 2025. Biochar-based nanocomposites from waste biomass: a sustainable approach for wastewater treatment and renewable bioenergy. Frontiers of Agricultural Science and Engineering 12:117−147

Tiwari A, Pandey M, Tiwari A, Tirkey A, Chandravanshi R, et al. 2025. Harnessing the potential of invasive plants biomass for biochar production and coal-mine spoil reclamation: a review. Bioresource Technology Reports 32:102350

Loc NX, Do TM. 2025. Optimizing biochar production: a review of recent progress in lignocellulosic biomass pyrolysis. Frontiers of Agricultural Science and Engineering 12:148−172

Gai S, Han L, Xu X, Feng Z, Lou F, et al. 2025. Sustainable and safe biochar-based composites from ZIF-8 and artificial humic acid for enhanced environmental remediation of Cu(II) and tetracycline in water. Process Safety and Environmental Protection 203:108022

Kumar A, Bhattacharya T, Shaikh WA, Chakraborty S, Owens G, et al. 2022. Valorization of fruit waste-based biochar for arsenic removal in soils. Environmental Research 213:113710

Cha JS, Park SH, Jung SC, Ryu C, Jeon JK, et al. 2016. Production and utilization of biochar: a review. Journal of Industrial and Engineering Chemistry 40:1−15

Funke A, Ziegler F. 2010. Hydrothermal carbonization of biomass: a summary and discussion of chemical mechanisms for process engineering. Biofuels, Bioproducts and Biorefining 4(2):160−177

You S, Ok YS, Chen SS, Tsang DCW, Kwon EE, et al. 2017. A critical review on sustainable biochar system through gasification: energy and environmental applications. Bioresource Technology 246:242−253

Tomczyk A, Sokołowska Z, Boguta P. 2020. Biochar physicochemical properties: pyrolysis temperature and feedstock kind effects. Reviews in Environmental Science and Bio/Technology 19(1):191−215

Banik C, Lawrinenko M, Bakshi S, Laird DA. 2018. Impact of pyrolysis temperature and feedstock on surface charge and functional group chemistry of biochars. Journal of Environmental Quality 47(3):452−461

Ippolito JA, Cui L, Kammann C, Wrage-Mönnig N, Estavillo JM, et al. 2020. Feedstock choice, pyrolysis temperature and type influence biochar characteristics: a comprehensive meta-data analysis review. Biochar 2(4):421−438

Zhao L, Cao X, Mašek O, Zimmerman A. 2013. Heterogeneity of biochar properties as a function of feedstock sources and production temperatures. Journal of Hazardous Materials 256:1−9

Gomez-Eyles JL, Beesley L, Moreno-Jimenez E, et al. 2013. The potential of biochar amendments to remediate contaminated soils. In Biochar and Soil Biota. eds. Ladygina N, Rineau F. Boca Raton: CRC Press. pp. 108−141 doi: 10.1201/b14585-6

Kharel G, Sacko O, Feng X, Morris JR, Phillips CL, et al. 2019. Biochar surface oxygenation by ozonization for super high cation exchange capacity. ACS Sustainable Chemistry & Engineering 7(19):16410−16418

Inyang M, Gao B, Pullammanappallil P, Ding W, Zimmerman AR. 2010. Biochar from anaerobically digested sugarcane bagasse. Bioresource Technology 101(22):8868−8872

Cho DW, Kwon G, Yoon K, Tsang YF, Ok YS, et al. 2017. Simultaneous production of syngas and magnetic biochar via pyrolysis of paper mill sludge using CO₂ as reaction medium. Energy Conversion and Management 145:1−9

Hossain MK, Strezov V, Chan KY, Ziolkowski A, Nelson PF. 2011. Influence of pyrolysis temperature on production and nutrient properties of wastewater sludge biochar. Journal of Environmental Management 92(1):223−228

Xu X, Tu R, Sun Y, Wu Y, Jiang E, et al. 2019. The influence of combined pretreatment with surfactant/ultrasonic and hydrothermal carbonization on fuel properties, pyrolysis and combustion behavior of corn stalk. Bioresource Technology 271:427−438

Yu H, Zou W, Chen J, Chen H, Yu Z, et al. 2019. Biochar amendment improves crop production in problem soils: a review. Journal of Environmental Management 232:8−21

Deal C, Brewer CE, Brown RC, Okure MAE, Amoding A. 2012. Comparison of kiln-derived and gasifier-derived biochars as soil amendments in the humid tropics. Biomass and Bioenergy 37:161−168

Ronsse F, van Hecke S, Dickinson D, Prins W. 2013. Production and characterization of slow pyrolysis biochar: influence of feedstock type and pyrolysis conditions. GCB Bioenergy 5(2):104−115

Angın D. 2013. Effect of pyrolysis temperature and heating rate on biochar obtained from pyrolysis of safflower seed press cake. Bioresource Technology 128:593−597

Lehmann J, Rillig MC, Thies J, Masiello CA, Hockaday WC, et al. 2011. Biochar effects on soil biota – a review. Soil Biology and Biochemistry 43(9):1812−1836

Park JH, Ok YS, Kim SH, Cho JS, Heo JS, et al. 2015. Evaluation of phosphorus adsorption capacity of sesame straw biochar on aqueous solution: influence of activation methods and pyrolysis temperatures. Environmental Geochemistry and Health 37(6):969−983

Zhao B, O'Connor D, Zhang J, Peng T, Shen Z, et al. 2018. Effect of pyrolysis temperature, heating rate, and residence time on rapeseed stem derived biochar. Journal of Cleaner Production 174:977−987

Lee JW, Kidder M, Evans BR, Paik S, Buchanan III AC, et al. 2010. Characterization of biochars produced from cornstovers for soil amendment. Environmental Science & Technology 44(20):7970−7974

Barszcz W, Łożyńska M, Molenda J. 2024. Impact of pyrolysis process conditions on the structure of biochar obtained from apple waste. Scientific Reports 14:10501

Benavente V, Fullana A. 2015. Torrefaction of olive mill waste. Biomass and Bioenergy 73:186−194

Chen WH, Zhuang YQ, Liu SH, Juang TT, Tsai CM. 2016. Product characteristics from the torrefaction of oil palm fiber pellets in inert and oxidative atmospheres. Bioresource Technology 199:367−374

Do PTM, Nguyen LX. 2024. A review of thermochemical decomposition techniques for biochar production. Environment, Development and Sustainability

Zheng C, Zhang W, Guo Z, Jin Y, Li J, et al. 2026. Unveiling synergistic effect of potassium permanganate and potassium ferrate to manufacture magnetic biochar by low-temperature pyrolysis for efficient adsorption of tetracycline and copper. Chemical Engineering Science 321:122745

Qiu T, Xie K, Liu C, Ahmad F, Zhao W, et al. 2025. Microwave-assisted pyrolysis for advanced sustainable carbon materials. Sustainable Carbon Materials 1:e011

Gabhane JW, Bhange VP, Patil PD, Bankar ST, Kumar S. 2020. Recent trends in biochar production methods and its application as a soil health conditioner: a review. SN Applied Sciences 2(7):1307

Williams CL, Westover TL, Emerson RM, Tumuluru JS, Li C. 2016. Sources of biomass feedstock variability and the potential impact on biofuels production. BioEnergy Research 9(1):1−14

Ippolito JA, Strawn DG, Scheckel KG, Novak JM, Ahmedna M, et al. 2012. Macroscopic and molecular investigations of copper sorption by a steam-activated biochar. Journal of Environmental Quality 41(4):1150−1156

Ippolito JA, Spokas KA, Novak JM, Lentz RD, Cantrell KB. 2015. Biochar elemental composition and factors influencing nutrient retention. In Biochar for Environmental Management: Science, Technology and Implementation, eds. Lehmann J, Joseph S. London: Routledge. pp. 139−163 doi: 10.4324/9780203762264

Choudhary TK, Khan KS, Hussain Q, Ahmad M, Ashfaq M. 2019. Feedstock-induced changes in composition and stability of biochar derived from different agricultural wastes. Arabian Journal of Geosciences 12(19):617

Basu P. 2010. Biomass gasification and pyrolysis. Burlington, MA: Academic Press. doi: 10.1016/C2009-0-20099-7

Yang H, Yan R, Chen H, Lee DH, Zheng C. 2007. Characteristics of hemicellulose, cellulose and lignin pyrolysis. Fuel 86:1781−1788

Chen B, Chen Z. 2009. Sorption of naphthalene and 1-naphthol by biochars of orange peels with different pyrolytic temperatures. Chemosphere 76(1):127−133

Zhang T, Walawender WP, Fan LT, Fan M, Daugaard D, et al. 2004. Preparation of activated carbon from forest and agricultural residues through CO₂ activation. Chemical Engineering Journal 105(1−2):53−59

Qiu T, Cao W, Xie K, Ahmad F, Zhao W, et al. 2025. CO₂ capture performances of H₃PO₄/KOH activated microwave pyrolyzed porous biochar. Sustainable Carbon Materials 1:e004

Janu R, Mrlik V, Ribitsch D, Hofman J, Sedláček P, et al. 2021. Biochar surface functional groups as affected by biomass feedstock, biochar composition and pyrolysis temperature. Carbon Resources Conversion 4:36−46

Yaashikaa PR, Kumar PS, Varjani S, Saravanan A. 2020. A critical review on the biochar production techniques, characterization, stability and applications for circular bioeconomy. Biotechnology Reports 28:e00570

Adhikari S, Moon E, Timms W. 2024. Identifying biochar production variables to maximise exchangeable cations and increase nutrient availability in soils. Journal of Cleaner Production 446:141454

Ambaye TG, Vaccari M, van Hullebusch ED, Amrane A, Rtimi S. 2021. Mechanisms and adsorption capacities of biochar for the removal of organic and inorganic pollutants from industrial wastewater. International Journal of Environmental Science and Technology 18(10):3273−3294

Liu S, Han X, Li S, Xuan W, Wei A. 2022. Stimulating nitrate removal with significant conversion to nitrogen gas using biochar-based nanoscale zerovalent iron composites. Water 14(18):2877

Yakout SM. 2015. Monitoring the changes of chemical properties of rice straw–derived biochars modified by different oxidizing agents and their adsorptive performance for organics. Bioremediation Journal 19(2):171−182

An X, Zhu Z, Luo X, Chen C, Liu T, et al. 2025. Effects of raw materials and pyrolysis temperatures on physicochemical properties of biochars derived from hemp stalks. Plants 14(16):2564

Zhang N, Xing J, Wei L, Liu C, Zhao W, et al. 2025. The potential of biochar to mitigate soil acidification: a global meta-analysis. Biochar 7(1):49

Li L, Yang Y, Lin Y, Deng G. 2023. Preparation of four kinds of biochar and its application to soil improvement. Guangdong Chemical Industry 50:46−48

Lu HL, Li KW, Nkoh JN, Shi YXX, He X, et al. 2022. Effects of the increases in soil pH and pH buffering capacity induced by crop residue biochars on available Cd contents in acidic paddy soils. Chemosphere 301:134674

Wang Q, Wang B, Lee X, Lehmann J, Gao B. 2018. Sorption and desorption of Pb(II) to biochar as affected by oxidation and pH. Science of the Total Environment 634:188−194

Chacón FJ, Sánchez-Monedero MA, Lezama L, Cayuela ML. 2020. Enhancing biochar redox properties through feedstock selection, metal preloading and post-pyrolysis treatments. Chemical Engineering Journal 395:125100

Klüpfel L, Keiluweit M, Kleber M, Sander M. 2014. Redox properties of plant biomass-derived black carbon (biochar). Environmental Science & Technology 48:5601−5611

Wu S, Cai X, Liao Z, He W, Shen J, et al. 2022. Redox properties of nano-sized biochar derived from wheat straw biochar. RSC Advances 12(18):11039−11046

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

Tan XF, Liu YG, Gu YL, Xu Y, Zeng GM, et al. 2016. Biochar-based nano-composites for the decontamination of wastewater: a review. Bioresource Technology 212:318−333

Zeng X, Liu B, Zhang Q, Huang X, Liu X. 2021. Preparation of magnetic biochar sphere and its adsorption properties for Pb(II) in soil. Energy Environmental Protection 35:50−57

He K, Sun A, Guo Z, Zheng C, Jin Y, et al. 2025. Preparation of nano zero-valent iron-doped magnetic biochar from different types of iron salts: comparing their adsorption capability for sulfamethoxazole. Journal of Environmental Chemical Engineering 13(5):119127

Qiang R, Feng S, Li W, Yin L, Ma Q, et al. 2022. Biomass-derived magnetic carbon composites towards microwave absorption. Journal of Textile Research 43:21−27

Zhang C, Zhao S, Huang Q, Liu J, Zhang Q. 2025. Adsorptive-photocatalytic removal of tetracycline from wastewater by Fe₃O₄- and SnO₂-containing biochar nanocomposites. Biochar 7(1):38

Yu J, Zhao Y, Xiao Y, Jiang H, Zhang J, et al. 2019. Study on preparation and characterization of tobacco stems magnetic biochar composites and its adsorbing capacity. Jiangsu Agricultural Sciences 47:257−262

Chausali N, Saxena J, Prasad R. 2021. Nanobiochar and biochar based nanocomposites: advances and applications. Journal of Agriculture and Food Research 5:100191

Qiao Y, Ren T, Dou K, Yin Y, Zhu H, et al. 2024. Research progress on the removal of heavy metals from polluted water using magnetic biochars. Guangdong Chemical Industry 51:60−64

Song S, Xu J, Song X, Yu Y. 2022. Preparation of magnetic biochar and its application in polluted water. Chemical Industry and Engineering Progress 41:6586−6605

Feng Z, Yuan R, Wang F, Chen Z, Zhou B, et al. 2021. Preparation of magnetic biochar and its application in catalytic degradation of organic pollutants: a review. Science of the Total Environment 765:142673

Zhang M, Gao B, Varnoosfaderani S, Hebard A, Yao Y, et al. 2013. Preparation and characterization of a novel magnetic biochar for arsenic removal. Bioresource Technology 130:457−462

Chen B, Chen Z, Lv S. 2011. A novel magnetic biochar efficiently sorbs organic pollutants and phosphate. Bioresource Technology 102(2):716−723

Jin L, Di G, Shi D, Li Q, Li X, et al. 2025. Magnetic Fe/S-modified porous carbon activates peracetic acid for emerging contaminant removal: unveiling active sites and structure-activity relationships. Water Research 286:124291

Quan G, Sun W, Yan J, Lan Y. 2014. Nanoscale zero-valent iron supported on biochar: characterization and reactivity for degradation of acid orange 7 from aqueous solution. Water, Air, & Soil Pollution 225(11):2195

Lyu H, Gao B, He F, Zimmerman AR, Ding C, et al. 2018. Effects of ball milling on the physicochemical and sorptive properties of biochar: experimental observations and governing mechanisms. Environmental Pollution 233:54−63

Zhang H, Huang H, Fang Y, Cai J, Lv X, et al. 2025. Synthesis of magnetic biochar Co-doped with sulfur, iron, and manganese via a novel modification method for simultaneous Cd and Pb remediation. Separation and Purification Technology 363:132025

Zhong C, Guo Z, Hang J, Xu S, Song H, et al. 2024. An efficient and general oxidative magnetization for preparation of versatile magnetic porous biochar at low temperature. Journal of Environmental Chemical Engineering 12(2):112187

Banat FA, Al-Bashir B, Al-Asheh S, Hayajneh O. 2000. Adsorption of phenol by bentonite. Environmental Pollution 107(3):391−398

Raghuwanshi VS, Garnier G. 2025. Nanoparticle decorated cellulose nanocrystals (CNC) composites for energy, catalysis, and biomedical applications. Advanced Functional Materials 35(2):2412869

Yao Y, Gao B, Chen J, Zhang M, Inyang M, et al. 2013. Engineered carbon (biochar) prepared by direct pyrolysis of Mg-accumulated tomato tissues: characterization and phosphate removal potential. Bioresource Technology 138:8−13

Li C, Zhang L, Gao Y, Li A. 2018. Facile synthesis of nano ZnO/ZnS modified biochar by directly pyrolyzing of zinc contaminated corn stover for Pb(II), Cu(II) and Cr(VI) removals. Waste Management 79:625−637

Zadehnazari A. 2023. Metal oxide/polymer nanocomposites: a review on recent advances in fabrication and applications. Polymer-Plastics Technology and Materials 62(5):655−700

Fang C, Zhang T, Li P, Jiang R, Wu S, et al. 2015. Phosphorus recovery from biogas fermentation liquid by Ca–Mg loaded biochar. Journal of Environmental Sciences 29:106−114

Wang H, Zhang Z, Sun R, Lin H, Gong L, et al. 2015. HPV infection and anemia status stratify the survival of early T2 laryngeal squamous cell carcinoma. Journal of Voice 29(3):356−362

Wang SH, Stevenson KB, Hines L, Mediavilla JR, Khan Y, et al. 2015. Evaluation of repetitive element polymerase chain reaction for surveillance of methicillin-resistant Staphylococcus aureus at a large academic medical center and community hospitals. Diagnostic Microbiology and Infectious Disease 81(1):13−17

Lawrinenko M, Jing D, Banik C, Laird DA. 2017. Aluminum and iron biomass pretreatment impacts on biochar anion exchange capacity. Carbon 118:422−430

Zhang M, Gao B, Yao Y, Xue Y, Inyang M. 2012. Synthesis of porous MgO-biochar nanocomposites for removal of phosphate and nitrate from aqueous solutions. Chemical Engineering Journal 210:26−32

Cope CO, Webster DS, Sabatini DA. 2014. Arsenate adsorption onto iron oxide amended rice husk char. Science of the Total Environment 488:554−561

Song Z, Lian F, Yu Z, Zhu L, Xing B, et al. 2014. Synthesis and characterization of a novel MnO_x-loaded biochar and its adsorption properties for Cu²⁺ in aqueous solution. Chemical Engineering Journal 242:36−42

Wang MC, Sheng GD, Qiu YP. 2015. A novel manganese-oxide/biochar composite for efficient removal of lead(II) from aqueous solutions. International Journal of Environmental Science and Technology 12(5):1719−1726

Hu X, Ding Z, Zimmerman AR, Wang S, Gao B. 2015. Batch and column sorption of arsenic onto iron-impregnated biochar synthesized through hydrolysis. Water Research 68:206−216

Kelarakis A. 2024. In situ generation of nanoparticles on and within polymeric materials. Polymers 16(11):1611

Liang J, Li X, Yu Z, Zeng G, Luo Y, et al. 2017. Amorphous MnO₂ modified biochar derived from aerobically composted swine manure for adsorption of Pb(II) and Cd(II). ACS Sustainable Chemistry & Engineering 5(6):5049−5058

Guo D, Feng D, Zhang Y, Zhang Z, Wu J, et al. 2022. Synergistic mechanism of biochar-nano TiO₂ adsorption-photocatalytic oxidation of toluene. Fuel Processing Technology 229:107200

Zhang L, Huang X, Liu L, Nasar NKA, Gu X, et al. 2025. Fabrication of organic/inorganic nanocomposites: from traditional synthesis to additive manufacturing. Advanced Materials 37(37):2505504

Tang J, Lv H, Gong Y, Huang Y. 2015. Preparation and characterization of a novel graphene/biochar composite for aqueous phenanthrene and mercury removal. Bioresource Technology 196:355−363

Pi L, Jiang R, Zhou W, Zhu H, Xiao W, et al. 2015. G-C₃N₄ Modified biochar as an adsorptive and photocatalytic material for decontamination of aqueous organic pollutants. Applied Surface Science 358:231−239

Devi P, Saroha AK. 2014. Synthesis of the magnetic biochar composites for use as an adsorbent for the removal of pentachlorophenol from the effluent. Bioresource Technology 169:525−531

Devi P, Saroha AK. 2015. Simultaneous adsorption and dechlorination of pentachlorophenol from effluent by Ni–ZVI magnetic biochar composites synthesized from paper mill sludge. Chemical Engineering Journal 271:195−203

Zhou Y, Gao B, Zimmerman AR, Fang J, Sun Y, et al. 2013. Sorption of heavy metals on chitosan-modified biochars and its biological effects. Chemical Engineering Journal 231:512−518

Zhang M, Gao B, Yao Y, Inyang M. 2013. Phosphate removal ability of biochar/MgAl-LDH ultra-fine composites prepared by liquid-phase deposition. Chemosphere 92(8):1042−1047

Wang Y, Peng Z, Yang Y, Li Z, Wen Y, et al. 2022. Auricularia auricula biochar supported γ-FeOOH nanoarrays for electrostatic self-assembly and pH-responsive controlled release of herbicide and fertilizer. Chemical Engineering Journal 437:134984

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

Nadarajah K, Asharp T, Jeganathan Y. 2024. Biochar from waste biomass, its fundamentals, engineering aspects, and potential applications: an overview. Water Science & Technology 89(5):1211−1239

Zhang A, Li X, Xing J, Xu G. 2020. Adsorption of potentially toxic elements in water by modified biochar: a review. Journal of Environmental Chemical Engineering 8(4):104196

Conte P, Bertani R, Sgarbossa P, Bambina P, Schmidt HP, et al. 2021. Recent developments in understanding biochar's physical–chemistry. Agronomy 11(4):615

Tan XF, Liu SB, Liu YG, Gu YL, Zeng GM, et al. 2017. Biochar as potential sustainable precursors for activated carbon production: multiple applications in environmental protection and energy storage. Bioresource Technology 227:359−372

Rayhan TH, Yap CN, Yulisa A, Rubiyatno, Popescu I, et al. 2022. Engineered nanoparticles for wastewater treatment system. Civil and Sustainable Urban Engineering 2(2):56−66

Rajapaksha AU, Chen SS, Tsang DCW, Zhang M, Vithanage M, et al. 2016. Engineered/designer biochar for contaminant removal/immobilization from soil and water: potential and implication of biochar modification. Chemosphere 148:276−291

Inyang M, Gao B, Zimmerman A, Zhou Y, Cao X. 2015. Sorption and cosorption of lead and sulfapyridine on carbon nanotube-modified biochars. Environmental Science and Pollution Research 22(3):1868−1876

Lu L, Shan R, Shi Y, Wang S, Yuan H. 2019. A novel TiO₂/biochar composite catalysts for photocatalytic degradation of methyl orange. Chemosphere 222:391−398

Fayad E, Alsunbul M, Alazragi RS, Ebada A, Ali HS, et al. 2025. Magnetic chitosan kaolinite cellulose nanofibril cryogel beads for efficient removal of methylene blue from water. Scientific Reports 15:41178

Ma Y, Lu T, Tang J, Li P, Mašek O, et al. 2022. One-pot hydrothermal synthesis of magnetic N-doped sludge biochar for efficient removal of tetracycline from various environmental waters. Separation and Purification Technology 297:121426

Khan ZH, Li Z, Gao M, Islam MS, Xiao L, et al. 2023. Simultaneous and efficient removal of Cd(II) and As(III) by a magnesium-manganese codoped biochar composite: sorption performance and governing mechanisms. Journal of Environmental Chemical Engineering 11(3):109919

Yi Y, Fu Y, Wang Y, Xu Z, Diao Z. 2024. Lanthanum/iron co-modified biochar for highly efficient adsorption of low-concentration phosphate from aqueous solution. Journal of Environmental Chemical Engineering 12(2):111876

Sharma M, Sharma K, Kumar D, Gill FS, Ichikawa T, et al. 2025. Process analysis of aqueous ciprofloxacin adsorption by biochar–magnetite nanocomposites. Discover Applied Sciences 7(10):1216

Nurlan N, Nurmyrza M, Han S, Lee W. 2024. Enhanced reductive removal of aqueous Hg(II) by a novel Pd-Cu-BTC catalyst. Chemical Engineering Journal 489:151276

Zhu C, Zhang J, Huang G, Zhu DZ. 2024. UV-modified biochar-Bacillus subtilis composite: an effective method for enhancing Cd(II) adsorption from water. Biochemical Engineering Journal 212:109527

Deng Z, Ma Y, Zhu J, Zeng C, Mu R, et al. 2024. Novel insights into ferrate (VI) activation by Mn-modified sludge biochar for sulfamethoxazole degradation: dominance of hydroxyl group and Mn-O bond in the non-radical pathway. Separation and Purification Technology 349:127679

Gokulan R, Prabhu GG, Jegan J. 2019. Remediation of complex remazol effluent using biochar derived from green seaweed biomass. International Journal of Phytoremediation 21(12):1179−1189

Ganguly P, Sarkhel R, Das P. 2020. Synthesis of pyrolyzed biochar and its application for dye removal: batch, kinetic and isotherm with linear and non-linear mathematical analysis. Surfaces and Interfaces 20:100616

Praveen S, Jegan J, Bhagavathi Pushpa T, Gokulan R, Bulgariu L. 2022. Biochar for removal of dyes in contaminated water: an overview. Biochar 4(1):10

Praveen S, Gokulan R, Pushpa TB, Jegan J. 2021. Techno-economic feasibility of biochar as biosorbent for basic dye sequestration. Journal of the Indian Chemical Society 98(8):100107

Viswanthan SP, Neelamury SP, Parakkuzhiyil S, Njazhakunnathu GV, Sebastian A, et al. 2022. Removal efficiency of methylene blue from aqueous medium using biochar derived from Phragmites karka, a highly invasive wetland weed. Biomass Conversion and Biorefinery 12(8):3257−3273

Fan S, Wang Y, Wang Z, Tang J, Tang J, et al. 2017. Removal of methylene blue from aqueous solution by sewage sludge-derived biochar: adsorption kinetics, equilibrium, thermodynamics and mechanism. Journal of Environmental Chemical Engineering 5(1):601−611

Chen T, Luo L, Deng S, Shi G, Zhang S, et al. 2018. Sorption of tetracycline on H₃PO₄ modified biochar derived from rice straw and swine manure. Bioresource Technology 267:431−437

Gupta S, Sireesha S, Sreedhar I, Patel CM, Anitha KL. 2020. Latest trends in heavy metal removal from wastewater by biochar based sorbents. Journal of Water Process Engineering 38:101561

Qiu B, Tao X, Wang H, Li W, Ding X, et al. 2021. Biochar as a low-cost adsorbent for aqueous heavy metal removal: a review. Journal of Analytical and Applied Pyrolysis 155:105081

Wang Y, Li H, Lin S. 2022. Advances in the study of heavy metal adsorption from water and soil by modified biochar. Water 14(23):3894

Ferraro G, Pecori G, Rosi L, Bettucci L, Fratini E, et al. 2024. Biochar from lab-scale pyrolysis: influence of feedstock and operational temperature. Biomass Conversion and Biorefinery 14(5):5901−5911

Qiu B, Shao Q, Shi J, Yang C, Chu H. 2022. Application of biochar for the adsorption of organic pollutants from wastewater: modification strategies, mechanisms and challenges. Separation and Purification Technology 300:121925

Liu Z, Zhang FS. 2009. Removal of lead from water using biochars prepared from hydrothermal liquefaction of biomass. Journal of Hazardous Materials 167(1−3):933−939

Inyang MI, Gao B, Yao Y, Xue Y, Zimmerman A, et al. 2016. A review of biochar as a low-cost adsorbent for aqueous heavy metal removal. Critical Reviews in Environmental Science and Technology 46(4):406−433

Zhang W, Du W, Wang F, Xu H, Zhao T, et al. 2020. Comparative study on Pb²⁺ removal from aqueous solutions using biochars derived from cow manure and its vermicompost. Science of the Total Environment 716:137108

He M, Xu Z, Hou D, Gao B, Cao X, et al. 2022. Waste-derived biochar for water pollution control and sustainable development. Nature Reviews Earth & Environment 3(7):444−460

Chen G, Wang C, Tian J, Liu J, Ma Q, et al. 2020. Investigation on cadmium ions removal from water by different raw materials-derived biochars. Journal of Water Process Engineering 35:101223

Hassan M, Liu Y, Naidu R, Parikh SJ, Du J, et al. 2020. Influences of feedstock sources and pyrolysis temperature on the properties of biochar and functionality as adsorbents: a meta-analysis. Science of the Total Environment 744:140714

Shi J, Fan X, Tsang DCW, Wang F, Shen Z, et al. 2019. Removal of lead by rice husk biochars produced at different temperatures and implications for their environmental utilizations. Chemosphere 235:825−831

Hu X, Zhang R, Xia B, Ying R, Hu Z, et al. 2022. Effect of pyrolysis temperature on removal efficiency and mechanisms of Hg(II), Cd(II), and Pb(II) by maize straw biochar. Sustainability 14(15):9022

Wang S, Gao B, Zimmerman AR, Li Y, Ma L, et al. 2015. Removal of arsenic by magnetic biochar prepared from pinewood and natural hematite. Bioresource Technology 175:391−395

Zhang L, Zhang Q, Wang Y, Cui X, Liu Y, et al. 2023. Preparation and application of metal-modified biochar in the purification of micro-polystyrene polluted aqueous environment. Journal of Environmental Management 347:119158

Yan L, Kong L, Qu Z, Li L, Shen G. 2015. Magnetic biochar decorated with ZnS nanocrytals for Pb(II) removal. ACS Sustainable Chemistry & Engineering 3(1):125−132

Fan J, Chen X, Xu Z, Xu X, Zhao L, et al. 2020. One-pot synthesis of nZVI-embedded biochar for remediation of two mining arsenic-contaminated soils: arsenic immobilization associated with iron transformation. Journal of Hazardous Materials 398:122901

Ke S, Zhang P, Ou S, Zhang J, Chen J, et al. 2022. Spatiotemporal nutrient patterns, composition, and implications for eutrophication mitigation in the Pearl River Estuary, China. Estuarine, Coastal and Shelf Science 266:107749

Huang W, Zhang Y, Li D. 2017. Adsorptive removal of phosphate from water using mesoporous materials: a review. Journal of Environmental Management 193:470−482

Jung KW, Hwang MJ, Ahn KH, Ok YS. 2015. Kinetic study on phosphate removal from aqueous solution by biochar derived from peanut shell as renewable adsorptive media. International Journal of Environmental Science and Technology 12(10):3363−3372

Reddy KR, Xie T, Dastgheibi S. 2014. Evaluation of biochar as a potential filter media for the removal of mixed contaminants from urban storm water runoff. Journal of Environmental Engineering 140(12):04014043

Wang F, Xu X, Shi H, Wen Y, Huang T, et al. 2021. Preparation of Fe²⁺ modified calamus biochar and its adsorption characteristics towards phosphorus from aqueous solutions. Chinese Journal of Environmental Engineering 15:3493−3503

Meng F, Feng L, Yin H, Chen K, Hu G, et al. 2019. Assessment of nutrient removal and microbial population dynamics in a non-aerated vertical baffled flow constructed wetland for contaminated water treatment with composite biochar addition. Journal of Environmental Management 246:355−361

Xu K, Lin F, Dou X, Zheng M, Tan W, et al. 2018. Recovery of ammonium and phosphate from urine as value-added fertilizer using wood waste biochar loaded with magnesium oxides. Journal of Cleaner Production 187:205−214

Yu H, Chen H, Zhang P, Yao Y, Zhao L, et al. 2023. In situ self-sacrificial synthesis of polypyrrole/biochar composites for efficiently removing short- and long-chain perfluoroalkyl acid from contaminated water. Journal of Environmental Management 344:118745

Hussain A, Maitra J, Ali Khan K. 2017. Development of biochar and chitosan blend for heavy metals uptake from synthetic and industrial wastewater. Applied Water Science 7(8):4525−4537

Roy K, Verma KM, Vikrant K, Goswami M, Sonwani RK, et al. 2018. Removal of patent blue (V) dye using Indian bael shell biochar: characterization, application and kinetic studies. Sustainability 10(8):2669

Zhang Y, Wang T, Zhang X, Sun Y, Fan G, et al. 2024. Porous pie-like nitrogen-doped biochar as a metal-free peroxymonosulfate activator for sulfamethoxazole degradation: performance, DFT calculation and mechanism. Applied Surface Science 647:158965

Teymourian T, Teymoorian T, Kowsari E, Ramakrishna S. 2021. A review of emerging PFAS contaminants: sources, fate, health risks, and a comprehensive assortment of recent sorbents for PFAS treatment by evaluating their mechanism. Research on Chemical Intermediates 47(12):4879−4914

Gahrouei AE, Vakili S, Zandifar A, Pourebrahimi S. 2024. From wastewater to clean water: Recent advances on the removal of metronidazole, ciprofloxacin, and sulfamethoxazole antibiotics from water through adsorption and advanced oxidation processes (AOPs). Environmental Research 252:119029

Verma A, Sharma G, Kumar A, Dhiman P, Mola GT, et al. 2024. Microplastic pollutants in water: a comprehensive review on their remediation by adsorption using various adsorbents. Chemosphere 352:141365

Ahmed W, Mehmood S, Qaswar M, Ali S, Khan ZH, et al. 2021. Oxidized biochar obtained from rice straw as adsorbent to remove uranium (VI) from aqueous solutions. Journal of Environmental Chemical Engineering 9(2):105104

Maghsodian Z, Sanati AM, Mashifana T, Sillanpää M, Feng S, et al. 2022. Occurrence and distribution of antibiotics in the water, sediment, and biota of freshwater and marine environments: a review. Antibiotics 11(11):1461

Wu Q, Pan CG, Wang YH, Xiao SK, Yu KF. 2021. Antibiotics in a subtropical food web from the Beibu Gulf, South China: occurrence, bioaccumulation and trophic transfer. Science of the Total Environment 751:141718

Cheng D, Ngo HH, Guo W, Chang SW, Nguyen DD, et al. 2020. A critical review on antibiotics and hormones in swine wastewater: water pollution problems and control approaches. Journal of Hazardous Materials 387:121682

Sanganyado E, Gwenzi W. 2019. Antibiotic resistance in drinking water systems: occurrence, removal, and human health risks. Science of the Total Environment 669:785−797

Pham TLN, Nguyen DKT, Dang BT. 2024. Sorption of four antibiotics onto pristine biochar derived from macadamia nutshell. Bioresource Technology 394:130281

Xue Q, Lin H, Feng Q, Yang Y, Dong M, et al. 2025. Synergistic photocatalysis and Fenton-like process driven by a biochar-supported biochar/iron hydroxide oxide/bismuth molybdate S-type heterojunction for tetracycline degradation: mechanistic insights and degradation pathways. Applied Surface Science 679:161277

Chen M, Dai Y, Guo J, Yang H, Liu D, et al. 2019. Solvothermal synthesis of biochar@ZnFe₂O₄/BiOBr Z-scheme heterojunction for efficient photocatalytic ciprofloxacin degradation under visible light. Applied Surface Science 493:1361−1367

Wang C, Huang R, Sun R, Yang J, Sillanpää M. 2021. A review on persulfates activation by functional biochar for organic contaminants removal: synthesis, characterizations, radical determination, and mechanism. Journal of Environmental Chemical Engineering 9(5):106267

Qin Y, Zhang L, An T. 2017. Hydrothermal carbon-mediated Fenton-like reaction mechanism in the degradation of alachlor: direct electron transfer from hydrothermal carbon to Fe(III). ACS Applied Materials & Interfaces 9(20):17115−17124

Fan W, Shen X, Zhu Z, Liu X, Zhang H, et al. 2024. Rsearch progress on biochar materials for new pollutants removal in the aquatic environment: a mini-review. Frontiers of Environmental Science & Engineering 19(3):33

Shi G, Liu H, Chen H, Liu T, Liang D, et al. 2024. Nitrogen self-doped Chlorella biochar as a peroxydisulfate activator for sulfamethazine degradation: the dominant role of electron transfer. Journal of Cleaner Production 440:140951

Tran VS, Ngo HH, Guo W, Nguyen TH, Luong TML, et al. 2023. New chitosan-biochar composite derived from agricultural waste for removing sulfamethoxazole antibiotics in water. Bioresource Technology 385:129384

Lenka SP, Kah M, Padhye LP. 2021. A review of the occurrence, transformation, and removal of poly- and perfluoroalkyl substances (PFAS) in wastewater treatment plants. Water Research 199:117187

Rahman MF, Peldszus S, Anderson WB. 2014. Behaviour and fate of perfluoroalkyl and polyfluoroalkyl substances (PFASs) in drinking water treatment: a review. Water Research 50:318−340

Militao IM, Roddick FA, Bergamasco R, Fan L. 2021. Removing PFAS from aquatic systems using natural and renewable material-based adsorbents: a review. Journal of Environmental Chemical Engineering 9(4):105271

Krebsbach S, He J, Adhikari S, Olshansky Y, Feyzbar F, et al. 2023. Mechanistic understanding of perfluorooctane sulfonate (PFOS) sorption by biochars. Chemosphere 330:138661

Zhang Y, Tan X, Lu R, Tang Y, Qie H, et al. 2023. Enhanced removal of polyfluoroalkyl substances by simple modified biochar: adsorption performance and theoretical calculation. ACS ES&T Water 3(3):817−826

Krahn KM, Cornelissen G, Castro G, Arp HPH, Asimakopoulos AG, et al. 2023. Sewage sludge biochars as effective PFAS-sorbents. Journal of Hazardous Materials 445:130449

Deng J, Han J, Hou C, Zhang Y, Fang Y, et al. 2023. Efficient removal of per- and polyfluoroalkyl substances from biochar composites: cyclic adsorption and spent regenerant degradation. Chemosphere 341:140051

Tripathi A, Ekanayake A, Tyagi VK, Vithanage M, Singh R, et al. 2025. Emerging contaminants in polluted waters: harnessing Biochar's potential for effective treatment. Journal of Environmental Management 373:123778

Talukdar A, Kundu P, Bhattacharya S, Dutta N. 2024. Microplastic contamination in wastewater: sources, distribution, detection and remediation through physical and chemical-biological methods. Science of the Total Environment 916:170254

Ferraro G, Failler P. 2020. Governing plastic pollution in the oceans: institutional challenges and areas for action. Environmental Science & Policy 112:453−460

Kumar R, Verma A, Rakib MRJ, Gupta PK, Sharma P, et al. 2023. Adsorptive behavior of micro(nano)plastics through biochar: co-existence, consequences, and challenges in contaminated ecosystems. Science of the Total Environment 856:159097

Yuan F, Yue L, Zhao H, Wu H. 2020. Study on the adsorption of polystyrene microplastics by three-dimensional reduced graphene oxide. Water Science and Technology 81(10):2163−2175

Abdoul Magid ASI, Islam MS, Chen Y, Weng L, Li J, et al. 2021. Enhanced adsorption of polystyrene nanoplastics (PSNPs) onto oxidized corncob biochar with high pyrolysis temperature. Science of the Total Environment 784:147115

Ali I, Tan X, Li J, Peng C, Wan P, et al. 2023. Innovations in the development of promising adsorbents for the remediation of microplastics and nanoplastics – a critical review. Water Research 230:119526

Shi M, Wang X, Shao M, Lu L, Ullah H, et al. 2022. Resource utilization of typical biomass wastes as biochars in removing plasticizer diethyl phthalate from water: characterization and adsorption mechanisms. Frontiers of Environmental Science & Engineering 17(1):5

Wang J, Sun C, Huang QX, Chi Y, Yan JH. 2021. Adsorption and thermal degradation of microplastics from aqueous solutions by Mg/Zn modified magnetic biochars. Journal of Hazardous Materials 419:126486

Babalar M, Siddiqua S, Sakr MA. 2024. A novel polymer coated magnetic activated biochar-zeolite composite for adsorption of polystyrene microplastics: synthesis, characterization, adsorption and regeneration performance. Separation and Purification Technology 331:125582

Parashar N, Hait S. 2024. Cetyl trimethyl ammonium bromide-modified magnetic biochar-integrated sand filter for microplastics removal from secondary-treated sewage effluents: performance evaluation and mechanistic insights. Journal of Water Process Engineering 59:105035

Chaudhary R, Sangwan G, Kumar S, Sharma V. 2026. Turning trash into tools: agricultural waste-derived biochars and composites for microplastic removal from wastewater. RSC Sustainability 4(2):650−676

Shaheen JF, Eniola JO, Sizirici B. 2024. Adsorption of ibuprofen from aqueous solution by modified date palm biochar: performance, optimization, and life cycle assessment. Bioresource Technology Reports 25:101696

Moreira MT, Noya I, Feijoo G. 2017. The prospective use of biochar as adsorption matrix – a review from a lifecycle perspective. Bioresource Technology 246:135−141

Samaraweera H, Alam SS, Nawalage S, Parashar D, Khan AH, et al. 2023. Facile synthesis and life cycle assessment of Iron oxide-Douglas fir biochar hybrid for anionic dye removal from water. Journal of Water Process Engineering 56:104377

Shaheen J, Fseha YH, Sizirici B. 2022. Performance, life cycle assessment, and economic comparison between date palm waste biochar and activated carbon derived from woody biomass. Heliyon 8(12):e12388

Maiti P, Siddiqi H, Kumari U, Chatterjee A, Meikap BC. 2023. Adsorptive remediation of azo dye contaminated wastewater by ZnCl₂ modified bio-adsorbent: batch study and life cycle assessment. Powder Technology 415:118153

Norberto J, Zoroufchi Benis K, McPhedran KN, Soltan J. 2023. Microwave activated and iron engineered biochar for arsenic adsorption: life cycle assessment and cost analysis. Journal of Environmental Chemical Engineering 11(3):109904

Qin Y, Li G, An T, Yang Z. 2021. Advances in ecological and health risks of biochar during environmental applications. Chinese Science Bulletin 66(1):5−20

Mishra E, Kapse S, Jain S. 2023. Consideration about regeneration, reactivity, toxicity, and challenges of biochar-based nanocomposites. In Biochar-Based Nanocomposites for Contaminant Management, eds. Mishra D, Singh R, Khare P. Cham: Springer International Publishing. pp. 107−118 doi: 10.1007/978-3-031-28873-9_9

Zhou X, Li P, He Y. 2023. Content and risk of heavy metals and polycyclic aromatic hydrocarbons in biochar-based fertilizer. Environmental Science & Technology 46:219−226

Yamin H, Yaping Z, Zhenyan C, et al. 2021. Review of the research on content levels and application risk of polycyclic aromatic hydrocarbons in biochar. Environmental Chemistry 40:2378−2387

Kookana RS, Sarmah AK, Van Zwieten L, Krull E, Singh B. 2011. Biochar application to soil: agronomic and environmental benefits and unintended consequences. Advances in Agronomy 112:103−143

Nie R, Wang W, Cao L, Xu H, Chu G, et al. 2023. Quadruple functional modification of biochar and its sorption mechanisms of environmental contaminants: a review. Materials Reports 37:238−246

Wahab R, Dwivedi S, Umar A, Singh S, Hwang IH, et al. 2013. ZnO nanoparticles induce oxidative stress in Cloudman S91 melanoma cancer cells. Journal of Biomedical Nanotechnology 9(3):441−449

Liu J, Wen Y, Mo Y, Liu W, Yan X, et al. 2023. Chemical speciation determines combined cytotoxicity: examples of biochar and arsenic/chromium. Journal of Hazardous Materials 448:130855

Azargohar R, Dalai AK. 2008. Steam and KOH activation of biochar: experimental and modeling studies. Microporous and Mesoporous Materials 110(2−3):413−421

Corsi I, Winther-Nielsen M, Sethi R, Punta C, Della Torre C, et al. 2018. Ecofriendly nanotechnologies and nanomaterials for environmental applications: key issue and consensus recommendations for sustainable and ecosafe nanoremediation. Ecotoxicology and Environmental Safety 154:237−244

Baskar AV, Bolan N, Hoang SA, Sooriyakumar P, Kumar M, et al. 2022. Recovery, regeneration and sustainable management of spent adsorbents from wastewater treatment streams: a review. Science of the Total Environment 822:153555

El-Naggar A, Lee MH, Hur J, Lee YH, Igalavithana AD, et al. 2020. Biochar-induced metal immobilization and soil biogeochemical process: an integrated mechanistic approach. Science of the Total Environment 698:134112

Rubalcaba Medina A, Hansen SF, Rodriguez Macias FJ, Baun A. 2024. A design-phase environmental safe-and-sustainable-by-design categorization tool for the development and innovation of nano-enabled advanced materials (AdMaCat). Environmental Science: Nano 11(9):3761−3773

Islam T, Li Y, Cheng H. 2021. Biochars and engineered biochars for water and soil remediation: a review. Sustainability 13(17):9932