| [1] |
Islam MS, Ahmed MK, Raknuzzaman M, Habibullah-Al-Mamun M, Islam MK. 2015. Heavy metal pollution in surface water and sediment: a preliminary assessment of an urban river in a developing country. |
| [2] |
Shen Q, Wang Z, Yu Q, Cheng Y, Liu Z, et al. 2020. Removal of tetracycline from an aqueous solution using manganese dioxide modified biochar derived from Chinese herbal medicine residues. |
| [3] |
Lian F, Sun B, Song Z, Zhu L, Qi X, et al. 2014. Physicochemical properties of herb-residue biochar and its sorption to ionizable antibiotic sulfamethoxazole. |
| [4] |
Zhao S, Zhou T. 2016. Biosorption of methylene blue from wastewater by an extraction residue of Salvia miltiorrhiza Bge. |
| [5] |
Wei L, Huang Y, Huang L, Li Y, Huang Q, et al. 2020. The ratio of H/C is a useful parameter to predict adsorption of the herbicide metolachlor to biochars. |
| [6] |
Argun ME, Dursun S, Ozdemir C, Karatas M. 2007. Heavy metal adsorption by modified oak sawdust: thermodynamics and kinetics. |
| [7] |
Liang L, Xi F, Tan W, Meng X, Hu B, et al. 2021. Review of organic and inorganic pollutants removal by biochar and biochar-based composites. |
| [8] |
Houde M, Muir DCG, Kidd KA, Guildford S, Drouillard K, et al. 2008. Influence of lake characteristics on the biomagnification of persistent organic pollutants in lake trout food webs. |
| [9] |
Liu X, Pang H, Liu X, Li Q, Zhang N, et al. 2021. Orderly porous covalent organic frameworks-based materials: superior adsorbents for pollutants removal from aqueous solutions. |
| [10] |
Singh E, Kumar A, Mishra R, You S, Singh L, et al. 2021. Pyrolysis of waste biomass and plastics for production of biochar and its use for removal of heavy metals from aqueous solution. |
| [11] |
Crini G, Lichtfouse E, Wilson LD, Morin-Crini N. 2019. Conventional and non-conventional adsorbents for wastewater treatment. |
| [12] |
Han C, Pu H, Li H, Deng L, Huang S, et al. 2013. The optimization of As(V) removal over mesoporous alumina by using response surface methodology and adsorption mechanism. |
| [13] |
Huggins TM, Haeger A, Biffinger JC, Ren ZJ. 2016. Granular biochar compared with activated carbon for wastewater treatment and resource recovery. |
| [14] |
Oliveira FR, Patel AK, Jaisi DP, Adhikari S, Lu H, et al. 2017. Environmental application of biochar: current status and perspectives. |
| [15] |
Qi C, Wang R, Jia S, Chen J, Li Y, et al. 2021. Biochar amendment to advance contaminant removal in anaerobic digestion of organic solid wastes: a review. |
| [16] |
Kuzyakov Y, Bogomolova I, Glaser B. 2014. Biochar stability in soil: decomposition during eight years and transformation as assessed by compound-specific 14C analysis. |
| [17] |
Wang J, Xiong Z, Kuzyakov Y. 2016. Biochar stability in soil: meta-analysis of decomposition and priming effects. |
| [18] |
Tripathi M, Sahu JN, Ganesan P. 2016. Effect of process parameters on production of biochar from biomass waste through pyrolysis: a review. |
| [19] |
Yang GX, Jiang H. 2014. Amino modification of biochar for enhanced adsorption of copper ions from synthetic wastewater. |
| [20] |
Ma Y, Liu WJ, Zhang N, Li YS, Jiang H, et al. 2014. Polyethylenimine modified biochar adsorbent for hexavalent chromium removal from the aqueous solution. |
| [21] |
Cheng N, Wang B, Wu P, Lee X, Xing Y, et al. 2021. Adsorption of emerging contaminants from water and wastewater by modified biochar: a review. |
| [22] |
Li Y, Yu H, Liu L, Yu H. 2021. Application of co-pyrolysis biochar for the adsorption and immobilization of heavy metals in contaminated environmental substrates. |
| [23] |
Kong X, Liu Y, Pi J, Li W, Liao Q, et al. 2017. Low-cost magnetic herbal biochar: characterization and application for antibiotic removal. |
| [24] |
Shang J, Zong M, Yu Y, Kong X, Du Q, et al. 2017. Removal of chromium (VI) from water using nanoscale zerovalent iron particles supported on herb-residue biochar. |
| [25] |
Yang Y, Tan X, Almatrafi E, Ye S, Song B, et al. 2022. Alfalfa biochar supported Mg-Fe layered double hydroxide as filter media to remove trace metal(loid)s from stormwater. |
| [26] |
Lu Q, Li C. 2021. Comprehensive utilization of Chinese medicine residues for industry and environment protection: turning waste into treasure. |
| [27] |
Tao W, Jin J, Zheng Y, Li S. 2021. Current advances of resource utilization of herbal extraction residues in China. |
| [28] |
Saha A, Basak BB. 2020. Scope of value addition and utilization of residual biomass from medicinal and aromatic plants. |
| [29] |
Yang Y, Zhang R, Chen S, Zhu J, Wu P, et al. 2022. Arsenic(iii) removal from aqueous solution using TiO2-loaded biochar prepared by waste Chinese traditional medicine dregs. |
| [30] |
Wang C, Qiao J, Yuan J, Tang Z, Chu T, et al. 2024. Novel chitosan-modified biochar prepared from a Chinese herb residue for multiple heavy metals removal: characterization, performance and mechanism. |
| [31] |
Yuan J, Wang C, Tang Z, Chu T, Zheng C, et al. 2024. Biochar derived from traditional Chinese medicine residues: an efficient adsorbent for heavy metal Pb(II). |
| [32] |
Yuan J, Liu Y, Wen H, He Q, Li Z, et al. 2026. Phosphorus-modifiedbiochar from salvia miltiorrhiza dregs: synthesis, characterization, and dual-functional synergy for heavy metal immobilization and soilfertility augmentation. |
| [33] |
Wei S, Wang Y, Tang Z, Xu H, Wang Z, et al. 2021. A novel green synthesis of silver nanoparticles by the residues of Chinese herbal medicine and their biological activities. |
| [34] |
Qiu M, Liu L, Ling Q, Cai Y, Yu S, et al. 2022. Biochar for the removal of contaminants from soil and water: a review. |
| [35] |
Wang Y, Chen L, Zhu Y, Fang W, Tan Y, et al. 2024. Research status, trends, and mechanisms of biochar adsorption for wastewater treatment: a scientometric review. |
| [36] |
de Azevedo ARG, dos S Coutinho RA, Pereira CR, Cecchin D. 2022. Characterization of solid waste of restaurant and its energy generation potential: case study of Niterói, RJ, Brazil. |
| [37] |
Wang Y, Liu Y, Zhan W, Zheng K, Wang J, et al. 2020. Stabilization of heavy metal-contaminated soils by biochar: Challenges and recommendations. |
| [38] |
Fuertes-Mendizábal T, Huérfano X, Vega-Mas I, Torralbo F, Menéndez S, et al. 2019. Biochar reduces the efficiency of nitrification inhibitor 3,4-dimethylpyrazole phosphate (DMPP) mitigating N2O emissions. |
| [39] |
Katiyar R, Patel AK, Nguyen TB, Singhania RR, Chen CW, et al. 2021. Adsorption of copper (II) in aqueous solution using biochars derived from Ascophyllum nodosum seaweed. |
| [40] |
Patel AK, Singhania RR, Pal A, Chen CW, Pandey A, et al. 2022. Advances on tailored biochar for bioremediation of antibiotics, pesticides and polycyclic aromatic hydrocarbon pollutants from aqueous and solid phases. |
| [41] |
Qiu Z, Fu K, Yu D, Luo J, Shang J, et al. 2022. Radix Astragali residue-derived porous amino-laced double-network hydrogel for efficient Pb(II) removal: performance and modeling. |
| [42] |
McBeath AV, Smernik RJ, Krull ES, Lehmann J. 2014. The influence of feedstock and production temperature on biochar carbon chemistry: a solid-state 13C NMR study. |
| [43] |
Clemente JS, Beauchemin S, Thibault Y, MacKinnon T, Smith D. 2018. Differentiating inorganics in biochars produced at commercial scale using principal component analysis. |
| [44] |
Yuan H, Lu T, Wang Y, Huang H, Chen Y. 2014. Influence of pyrolysis temperature and holding time on properties of biochar derived from medicinal herb (Radix isatidis) residue and its effect on soil CO2 emission. |
| [45] |
Liu G, Zheng H, Jiang Z, Zhao J, Wang Z, et al. 2018. Formation and physicochemical characteristics of nano biochar: insight into chemical and colloidal stability. |
| [46] |
Song J, He Q, Hu X, Zhang W, Wang C, et al. 2019. Highly efficient removal of Cr(VI) and Cu(II) by biochar derived from Artemisia argyi stem. |
| [47] |
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. |
| [48] |
Zhang S, Wang J. 2021. Removal of chlortetracycline from water by Bacillus cereus immobilized on Chinese medicine residues biochar. |
| [49] |
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. |
| [50] |
Yang Y, Sun K, Han L, Jin J, Sun H, et al. 2018. Effect of minerals on the stability of biochar. |
| [51] |
Liu Y, Gao C, Wang Y, He L, Lu H, et al. 2020. Vermiculite modification increases carbon retention and stability of rice straw biochar at different carbonization temperatures. |
| [52] |
Chang Z, Tian L, Zhang J, Zhou D. 2022. Comparative study on the relative significance of low-/high-condensation aromatic moieties in biochar to organic contaminant sorption. |
| [53] |
Shang J, Pi J, Zong M, Wang Y, Li W, et al. 2016. Chromium removal using magnetic biochar derived from herb-residue. |
| [54] |
Spokas, Kurt A. 2010. Review of the stability of biochar in soils: predictability of O: C molar ratios. |
| [55] |
Choi YK, Kan E. 2019. Effects of pyrolysis temperature on the physicochemical properties of alfalfa-derived biochar for the adsorption of bisphenol A and sulfamethoxazole in water. |
| [56] |
Zhou XY, Xie F, Jiang M, Li KA, Tian SG. 2021. Physicochemical properties and lead ion adsorption of biochar prepared from Turkish gall residue at different pyrolysis temperatures. |
| [57] |
Yaashikaa PR, Senthil Kumar P, Varjani SJ, Saravanan A. 2019. Advances in production and application of biochar from lignocellulosic feedstocks for remediation of environmental pollutants. |
| [58] |
Wang Z, Liu K, Xie L, Zhu H, Ji S, et al. 2019. Effects of residence time on characteristics of biochars prepared via co-pyrolysis of sewage sludge and cotton stalks. |
| [59] |
Sun J, He F, Pan Y, Zhang Z. 2017. Effects of pyrolysis temperature and residence time on physicochemical properties of different biochar types. |
| [60] |
Zhang S, Yao Y, Li J, Wang L, Wang X, et al. 2023. Multi-factorial investigation of the effect of biochar of the secondary medicinal residue of snow lotus on the adsorption of two azo dyes, methyl red and methyl orange. |
| [61] |
Zhang K, Yao S, Gu S, Zhang Y, Kim H, et al. 2024. Modified biochar activated by traditional Chinese medicine extract and its removal of tetracycline. |
| [62] |
Li L, Xie Y, Chen K, Zhou J, Wang M, et al. 2024. Adsorption characteristics of ball milling-modified chinese medicine residue biochar toward quercetin. |
| [63] |
Li P, Zhao Z, Zhang M, Su H, Zhao T, et al. 2024. Exploring the potential of biochar derived from chinese herbal medicine residue for efficient removal of norfloxacin. |
| [64] |
Kong W, Zhang M, Liu Y, Gou J, Wei Q, et al. 2021. Physico-chemical characteristics and the adsorption of ammonium of biochar pyrolyzed from distilled spirit lees, tobacco fine and Chinese medicine residues. |
| [65] |
Shen B, Li G, Wang F, Wang Y, He C, et al. 2015. Elemental mercury removal by the modified bio-char from medicinal residues. |
| [66] |
Wang Z, Liu G, Zheng H, Li F, Ngo HH, et al. 2015. Investigating the mechanisms of biochar's removal of lead from solution. |
| [67] |
Zheng Z, Duan X. 2022. Mitigating the health effects of aqueous Cr(VI) with iron-modified biochar. |
| [68] |
Hou X, Deng Y, Dai M, Jiang X, Li S, et al. 2022. Migration and transformation of heavy metals in Chinese medicine residues during the process of traditional pyrolysis and solar pyrolysis. |
| [69] |
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. |
| [70] |
Yi Y, Tu G, Zhao D, Tsang PE, Fang Z. 2019. Biomass waste components significantly influence the removal of Cr(VI) using magnetic biochar derived from four types of feedstocks and steel pickling waste liquor. |
| [71] |
Fang Z, Qiu X, Huang R, Qiu X, Li M. 2011. Removal of chromium in electroplating wastewater by nanoscale zero-valent metal with synergistic effect of reduction and immobilization. |
| [72] |
Tie J, Sang S, Shang Z, Li Y, Xu Z, et al. 2022. Preparation of Al-loaded magnetic Chinese medicine residue-derived biochar and application of it in fluoride removal. |
| [73] |
Wang H, Lou X, Hu Q, Sun T. 2021. Adsorption of antibiotics from water by using Chinese herbal medicine residues derived biochar: preparation and properties studies. |
| [74] |
Shao F, Zhang X, Sun X, Shang JG. 2021. Antibiotic removal by activated biochar: performance, isotherm, and kinetic studies. |
| [75] |
Ren Y, Yang Y, Qu G, Ning P, Ren N, et al. 2023. HCl-assisted KOH activated Chinese medicine residue biochar as a new method to improve the purification capacity of lead-containing wastewater: experimental and mechanism studies. |
| [76] |
Chen X, Zhu X, Fan G, Wang X, Li H, et al. 2022. Enhanced adsorption of Pb(II) by phosphorus-modified chicken manure and Chinese medicine residue co-pyrolysis biochar. |
| [77] |
Hu B, Ai Y, Jin J, Hayat T, Alsaedi A, et al. 2020. Efficient elimination of organic and inorganic pollutants by biochar and biochar-based materials. |
| [78] |
Diao FM, Chen ML, Tong LY, Chen YN, Diao ZH. 2023. A green synthesized medicine residue carbon-based iron composite for the removal of chromium (VI) and cadmium (II): performance, kinetics and mechanism. |
| [79] |
Zheng Z, Duan X, Tie J. 2022. One-pot synthesis of a magnetic Zn/iron-based sludge/biochar composite for aqueous Cr(VI) adsorption. |
| [80] |
Li Z, Li M, Zheng T, Li Y, Liu X. 2019. Removal of tylosin and copper from aqueous solution by biochar stabilized nano-hydroxyapatite. |
| [81] |
Shang JG, Kong XR, He LL, Li WH, Liao QJH. 2016. Low-cost biochar derived from herbal residue: characterization and application for ciprofloxacin adsorption. |
| [82] |
Zhao Z, Li P, Zhang M, Feng W, Tang H, et al. 2024. Unlocking the potential of Chinese herbal medicine residue-derived biochar as an efficient adsorbent for high-performance tetracycline removal. |
| [83] |
Chen H, Zhang Y, Li J, Zhang P, Liu N. 2019. Preparation of pickling-reheating activated alfalfa biochar with high adsorption efficiency for p-nitrophenol: characterization, adsorption behavior, and mechanism. |
| [84] |
Zhang Y, Tang Z, Liu S, Xu H, Song Z. 2018. Study on adsorption of phenol from aqueous media using biochar of Chinese herb residue. |
| [85] |
Zhang S, Wang J, Zhang Y, Ma J, Huang L, et al. 2021. Applications of water-stable metal-organic frameworks in the removal of water pollutants: a review. |
| [86] |
Luo Z, Yao B, Yang X, Wang L, Xu Z, et al. 2022. Novel insights into the adsorption of organic contaminants by biochar: a review. |
| [87] |
Li X, Wang J, Xia L, Cheng R, Chen J, et al. 2023. Peroxymonosulfate activation by nitrogen-doped herb residue biochar for the degradation of tetracycline. |
| [88] |
Jia W, Wang H, Wu Q, Sun L, Si Q, et al. 2023. Insight into Chinese medicine residue biochar combined with ultrasound for persulfate activation in atrazine degradation: Acanthopanax senticosus precursors, synergistic effects and toxicity assessment. |
| [89] |
Jiang T, Wang B, Gao B, Cheng N, Feng Q, et al. 2023. Degradation of organic pollutants from water by biochar-assisted advanced oxidation processes: mechanisms and applications. |
| [90] |
Coha M, Farinelli G, Tiraferri A, Minella M, Vione D. 2021. Advanced oxidation processes in the removal of organic substances from produced water: potential, configurations, and research needs. |
| [91] |
Yu J, Zhu Z, Zhang H, Qiu Y, Yin D, et al. 2021. Stepwise carbonization of nanocellulose to N-doped carbons with structural transformation and enhanced peroxymonosulfate activation. |
| [92] |
Xiao S, Cheng M, Zhong H, Liu Z, Liu Y, et al. 2020. Iron-mediated activation of persulfate and peroxymonosulfate in both homogeneous and heterogeneous ways: a review. |
| [93] |
Liu N, Lu N, Yu H, Chen S, Quan X. 2021. Degradation of aqueous bisphenol A in the CoCN/Vis/PMS system: Catalyst design, reaction kinetic and mechanism analysis. |
| [94] |
Wang J, Wang S. 2019. Preparation, modification and environmental application of biochar: a review. |
| [95] |
Liu Z, Gao Z, Wu Q. 2021. Activation of persulfate by magnetic zirconium-doped manganese ferrite for efficient degradation of tetracycline. |
| [96] |
Li Z, Li M, Che Q, Li Y, Liu X. 2019. Synergistic removal of tylosin/sulfamethoxazole and copper by nano-hydroxyapatite modified biochar. |
| [97] |
Yu Z, Ji L, Zuo Y, Zhang F, Wei C, et al. 2023. Removal of tetracycline hydrochloride by ball-milled mulberry biochar. |
| [98] |
He Q, Bai Y, Lu Y, Cui B, Huang Z, et al. 2024. Isolation and characterization of cellulose nanocrystals from Chinese medicine residues. |
| [99] |
Vandana TU, Tripathy BK, Mishra RK, Sharma A, Mohanty K. 2025. A review on waste biomass-derived biochar: Production, characterisation, and advanced analytical techniques for pollutants assessment in water and wastewater. |
| [100] |
Stylianou M, Christou A, Dalias P, Polycarpou P, Michael C, et al. 2020. Physicochemical and structural characterization of biochar derived from the pyrolysis of biosolids, cattle manure and spent coffee grounds. |
| [101] |
Zhang A, Qiu Y, Chen D, Feng Y, Zhang B. 2024. Valorization of fruit waste by biochar production via thermochemical conversion: a mini-review. |
| [102] |
Sui F, Jiao M, Kang Y, Joseph S, Li L, et al. 2021. Investigating the cadmium adsorption capacities of crop straw biochars produced using various feedstocks and pyrolysis temperatures. |
| [103] |
Rangabhashiyam S, Balasubramanian P. 2019. The potential of lignocellulosic biomass precursors for biochar production: performance, mechanism and wastewater application—a review. |
| [104] |
Li Y, Xiong H, Xu T, Liu Q, Hu Y, et al. 2023. Measurement of lignocellulose components in traditional Chinese medicineresidues and establishment of classification guidelines. |
| [105] |
Deng Q, Li A, Luo L, Wu Y, Tang H, et al. 2023. Herbal biochar preparation and its application as soil amendment: is such disposal of traditional Chinese medicine residue cost-efficient towards carbon neutrality? |
| [106] |
Zhu X, Labianca C, He M, Luo Z, Wu C, et al. 2022. Life-cycle assessment of pyrolysis processes for sustainable production of biochar from agro-residues. |
| [107] |
He X, Wang Y, Tai MH, Lin A, Owyong S, et al. 2022. Integrated applications of water hyacinth biochar: a circular economy case study. |
| [108] |
Long X, Lu YL, Guo H, Tang YP. 2023. Recent advances in solid residues resource utilization in traditional Chinese medicine. |
| [109] |
Zhou Y, Zhou Z, Zeng J. 2025. Green synthesis and antibacterial application of carbon dots derived from traditional Chinese medicine: research progress and future challenges. |
| [110] |
Liang P, Bi T, Zhou Y, Wang C, Ma Y, et al. 2023. Carbonized Platycladus orientalis derived carbon dots accelerate hemostasis through activation of platelets and coagulation pathways. |
| [111] |
Zhang J, Hou Y, Xu X, Li Y, Sun Z, et al. 2025. Gardeniae Fructus derived natural small molecule-based carbon dots promoting activation and aggregation of platelets to accelerate hemostasis. |
| [112] |
Li X, Dai E, Li M, Kong R, Yuan J, et al. 2023. Aurantii fructus immaturus carbonisata-derived carbon dots and their anti-depression effect. |
| [113] |
Bian Z, Bao T, Sun X, Wang N, Mu Q, et al. 2024. Machine learning tools to assist the synthesis of antibacterial carbon dots. |
| [114] |
Shi W, Li J, Pu J, Cheng G, Liu Y, et al. 2025. Epigynum auritum-derived near-infrared carbon dots for bioimaging and antimicrobial applications. |