Abstract: This study aims to optimize the use of lacquer residue biomass (LBM). We investigated the ability of LBM to remove Pb²⁺ heavy metal ions and the typical cationic dye methylene blue (MB) and anionic dye Congo red (CR) by simultaneous adsorption from composite systems, as well as the relevant factors. Scanning electron microscopy (SEM), X-ray diffraction (XRD), and Fourier transform infrared spectroscopy (FTIR) were used to characterize adsorption behavior. The adsorption kinetics of Pb²⁺-MB/CR composite systems can be effectively characterized by the pseudo-second-order kinetic model (R²>0.97). In the Pb²⁺-MB composite system, adsorption was antagonistic with similar adsorption sites. However, in the Pb²⁺-CR composite system, we found that adsorption was synergistic with different adsorption sites, which led to a higher simultaneous adsorption capacity for a higher initial Pb²⁺-CR concentration, unlike the Pb²⁺-MB system. In both composite systems, an appropriate increase in LBM dosage and system temperature within a certain range was conducive to simultaneous adsorption and removal of Pb²⁺-MB/CR composite systems. The optimal solid–liquid ratio and temperature were 1∶‍75 and 30°C, respectively. The adsorption and removal rates of Pb²⁺ and MB were 99.98% and 90.49%, respectively, and those of Pb²⁺ and CR were 93.99% and 77.39%, respectively, in (50, 50) mg/L of Pb²⁺-MB/CR composite systems under these conditions. Adsorption removal of Pb²⁺ and MB improved with higher pH levels, and worsened with the increase of ionic strength in the solution, while the removal rate of CR showed an opposite trend. The coexisting anion and cation types had limited influence on the simultaneous adsorption removal of Pb²⁺, MB, and CR. The results of desorption showed that LBM can be utilized as a disposable material for simultaneously treating Pb²⁺-MB/CR composite systems. The simultaneous adsorption mechanisms of Pb²⁺-MB/CR mainly involved hydrogen bonding, π–π bonding interaction, and electrostatic interaction.

漆渣经微生物处理形成的生物质渣对同步吸附去除废水中重金属和染料的研究

[1]AbbasiA, AhmadI, Abd El-GawadHH, et al., 2024. Appraisal of the adsorption potential of novel modified gellan gum nanocomposite for the confiscation of methylene blue and malachite green. International Journal of Biological Macromolecules, 259:129221.

[2]AbegundeSM, OlasehindeEF, AdebayoMA, 2024. Green synthesis of ZnO nanoparticles using Nauclea latifolia fruit extract for adsorption of Congo red. Hybrid Advances, 5:100164.

[3]AlinezhadH, ZabihiM, KahfroushanD, 2020. Design and fabrication the novel polymeric magnetic boehmite nanocomposite (boehmite@Fe₃O₄@PLA@SiO₂) for the remarkable competitive adsorption of methylene blue and mercury ions. Journal of Physics and Chemistry of Solids, 144:109515.

[4]AlorabiAQ, AziziM, 2023. Effective removal of methyl green from aqueous environment using activated residual Dodonaea Viscosa : equilibrium, isotherm, and mechanism studies. Environmental Pollutants and Bioavailability, 35(1):2168761.

[5]AnCC, ZhangM, XiaoZH, et al., 2023. Lignocellulose/chitosan hybrid aerogel composited with fluorescence molecular probe for simultaneous adsorption and detection of heavy metal pollutants. Journal of Environmental Chemical Engineering, 11(6):111205.

[6]AngaruGKR, LingamdinneLP, ChoiYL, et al., 2021. Encapsulated zerovalent iron/nickel-fly ash zeolite foam for treating industrial wastewater contaminated by heavy metals. Materials Today Chemistry, 22:100577.

[7]AryeeAA, GaoCP, HanRP, et al., 2022. Functionalized magnetic biocomposite based on peanut husk for the efficient sequestration of basic dyes in single and binary systems: adsorption mechanism and antibacterial study. Journal of Environmental Chemical Engineering, 10(4):108205.

[8]AzeezL, AdebisiSA, AdejumoAL, et al., 2022. Adsorptive properties of rod-shaped silver nanoparticles-functionalized biogenic hydroxyapatite for remediating methylene blue and Congo red. Inorganic Chemistry Communications, 142:109655.

[9]BrahmaD, SaikiaH, 2022. Synthesis of ZrO₂/MgAl-LDH composites and evaluation of its isotherm, kinetics and thermodynamic properties in the adsorption of Congo red dye. Chemical Thermodynamics and Thermal Analysis, 7:100067.

[10]CaiL, 2018. Aniline degradation and dye decolorization with mixed bacteria in printing and dyeing wastewater. China Dyeing and Finishing, 44(17):39-43(in Chinese).

[11]CangJS, LiYJ, LiuDJ, et al., 2021. Separation of trace Pb(II) and Cd(II) in dyeing wastewater by carbon dioxide driven ionic liquid two-phase extraction. China Dyeing and Finishing, 47(11):67-70(in Chinese).

[12]ChangalvaeiM, NilforoushanMR, ArabmarkadehA, et al., 2021. Removal of Ni and Zn heavy metal ions from industrial waste waters using modified slag of electric arc furnace. Materials Research Express, 8(5):055506.

[13]ChanzuHA, OnyariJM, ShiunduPM, 2019. Brewers’ spent grain in adsorption of aqueous Congo red and malachite green dyes: batch and continuous flow systems. Journal of Hazardous Materials, 380:120897.

[14]ChenL, HuJ, HeYY, et al., 2024. Microwave-assisted pyrolysis of waste lignin to prepare biochar for Cu²⁺ highly-efficient adsorption: performance, kinetics and mechanism resolution. Separation and Purification Technology, 342:127070.

[15]ChenRP, GanCH, CaiBC, et al., 2024. Co-adsorption and selective-adsorption of heavy metals and dyes from aqueous solution by bio-based humus/chitosan hydrogels. Journal of Environmental Sciences, 145:193-204.

[16]DebnathS, DasR, 2023. Strong adsorption of CV dye by Ni ferrite nanoparticles for waste water purification: fits well the pseudo second order kinetic and Freundlich isotherm model. Ceramics International, 49(10):‍16199-16215.

[17]DuPY, XuL, KeZJ, et al., 2022. A highly efficient biomass-based adsorbent fabricated by graft copolymerization: kinetics, isotherms, mechanism and coadsorption investigations for cationic dye and heavy metal. Journal of Colloid and Interface Science, 616:12-22.

[18]FanC, LiangY, DongHQ, et al., 2018. Guanidinium ionic liquid-controlled synthesis of zeolitic imidazolate framework for improving its adsorption property. Science of the Total Environment, 640-641:163-173.

[19]GhafilAJ, MazloomG, AbdiJ, et al., 2024. Ti₃C₂T_x/ZIF-67 hybrid nanocomposite as a highly effective adsorbent for Pb(II) removal from water: synthesis and DFT calculations. Applied Surface Science, 643:158642.

[20]GuptaSV, KulkarniVV, AhmaruzzamanM, 2024. Fabrication of a bio-adsorbent material by grafting CeO₂ quantum dots (QDts) over Areca nut shell biochar using Saccharum officinarum extract as a solvent/capping agent for adsorption of methylene blue dye: synthesis, material analyses, adsorption kinetics and isotherms studies. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 680:132611.

[21]HajiahmadiZ, MohebA, MohammadiM, et al., 2024. Surface and mass transfer kinetic and equilibrium modeling of Pb(II) ions adsorption on hydroxyapatite scaffold: batch and fixed-bed column studies. Separation and Purification Technology, 343:127141.

[22]HanRP, ZhangJJ, HanP, et al., 2009. Study of equilibrium, kinetic and thermodynamic parameters about methylene blue adsorption onto natural zeolite. Chemical Engineering Journal, 145(3):496-504.

[23]HeS, SunJW, JinX, et al., 2023. Adsorption enhancement of Congo red dye from wastewater based on edamame shell originated activated carbon by the cations: experimental and theoretical studies. Diamond and Related Materials, 136:109930.

[24]IgberaseE, OsifoP, OfomajaA, 2018. Adsorption of metal ions by microwave assisted grafting of cross-linked chitosan beads. Equilibrium, isotherm, thermodynamic and desorption studies. Applied Organometallic Chemistry, 32(3):e4131.

[25]JiangJ, HuangXY, BaiJL, et al., 2022. Adsorption of clothianidin by potassium permanganate modified biochar in aqueous solution. Chinese Journal of Environmental Engineering, 16(4):1175-1185(in Chinese).

[26]KalamS, Abu-KhamsinSA, KamalMS, et al., 2021. Surfactant adsorption isotherms: a review. ACS Omega, 6(48):32342-32348.

[27]KhodabakhshiA, Mohammadi-MoghadamF, ShakeriK, et al., 2022. Equilibrium and thermodynamic studies on the biosorption of lead (II) by living and nonliving biomass of Penicillium notatum. Journal of Chemistry, 2022:3109212.

[28]KhoeeS, KoohrouSA, MoayeriS, 2024. Use of NIR/NaBH₄ combinatorial techniques for simultaneous and high-efficient adsorption of heavy metal ions from contaminated water by Chitosan/Au Janus microdisks. Surfaces and Interfaces, 44:103801.

[29]KimSH, ChungH, JeongS, et al., 2021. Identification of pH-dependent removal mechanisms of lead and arsenic by basic oxygen furnace slag: relative contribution of precipitation and adsorption. Journal of Cleaner Production, 279:123451.

[30]KyzasGZ, SiafakaPI, PavlidouEG, et al., 2015. Synthesis and adsorption application of succinyl-grafted chitosan for the simultaneous removal of zinc and cationic dye from binary hazardous mixtures. Chemical Engineering Journal, 259:438-448.

[31]LanHC, ZhangS, ZhangJY, et al., 2023. Water-soluble carbon nitride as phase-convertible adsorbents for removing heavy metals from water. Applied Surface Science, 614:156172.

[32]LiB, GuoJZ, LvKL, et al., 2019a. Adsorption of methylene blue and Cd(II) onto maleylated modified hydrochar from water. Environmental Pollution, 254:113014.

[33]LiB, LvJQ, GuoJZ, et al., 2019b. The polyaminocarboxylated modified hydrochar for efficient capturing methylene blue and Cu(II) from water. Bioresource Technology, 275:360-367.

[34]LiB, LiuJL, XuH, 2022. Synthesis of polyaminophosphonated-functionalized hydrochar for efficient sorption of Pb(II). Environmental Science and Pollution Research, 29(33):49808-49815.

[35]LiL, BaiYF, QiCH, et al., 2024. Adsorption of Pb(II) and Cu(II) by succinic anhydride-modified apple pomace. Biochemical Engineering Journal, 201:109136.

[36]LiPP, LiZ, LiuSY, et al., 2024. Imidazole/pyridine-based ionic liquids modified metal-organic frameworks for efficient adsorption of Congo red in water. Journal of Molecular Structure, 1303:137599.

[37]LiSH, LuoC, YanF, et al., 2023. Remediation of Pb(II) and Cd(II) in polluted waters with calcium thioglycolate-modified straw biochar. Environmental Pollution, 338:122638.

[38]LiSQ, FanZL, LiQ, et al., 2019. Magnetic metal-organic framework material and its application in printing and dyeing wastewater treatment (I). China Dyeing and Finishing, 45(22):53-56(in Chinese).

[39]LiangYQ, LiH, MaoXM, et al., 2020. Competitive adsorption of methylene blue and Cu(II) onto magnetic graphene oxide/alginate beads. Russian Journal of Physical Chemistry A, 94(12):2605-2613.

[40]LinJY, YeWY, XieM, et al., 2023. Environmental impacts and remediation of dye-containing wastewater. Nature Reviews Earth & Environment, 4(11):785-803.

[41]LiuB, LvP, WuRF, et al., 2023. Coal gasification fine slag based multifunctional nanoporous silica microspheres for synergistic adsorption of Pb(II) and Congo red. Separation and Purification Technology, 323:124478.

[42]LiuFJ, HeQ, SuL, et al., 2024. Adsorption properties of methylene blue by surface functionalized magnetic biochar with sodium alginate. Inorganic Chemicals Industry, 56(2):65-73(in Chinese).

[43]LiuS, HuangJH, ZhangW, et al., 2022. Investigation of the adsorption behavior of Pb(II) onto natural-aged microplastics as affected by salt ions. Journal of Hazardous Materials, 431:128643.

[44]LiuY, QiuGY, LiuYF, et al., 2022. Fabrication of CoFe-MOF materials by different methods and adsorption properties for Congo red. Journal of Molecular Liquids, 360:119405.

[45]LuXY, LiaoM, XieXM, et al., 2024. The potential of biomass residue formed from microbial treatment of lacquer residue for adsorption and removal of dye from wastewater. Acta Scientiae Circumstantiae, 44(4):‍‍82-94 (in Chinese).

[46]LvSW, LiuJM, MaH, et al., 2019. Simultaneous adsorption of methyl orange and methylene blue from aqueous solution using amino functionalized Zr-based MOFs. Microporous and Mesoporous Materials, 282:179-187.

[47]MaDS, YiH, LaiC, et al., 2021. Critical review of advanced oxidation processes in organic wastewater treatment. Chemosphere, 275:130104.

[48]MenesesIP, NovaesSD, DezottiRS, et al., 2022. CTAB-modified carboxymethyl cellulose/bagasse cryogels for the efficient removal of bisphenol A, methylene blue and Cr(VI) ions: batch and column adsorption studies. Journal of Hazardous Materials, 421:126804.

[49]MondalMIH, ChakrabortySC, RahmanMS, et al., 2024. Adsorbents from rice husk and shrimp shell for effective removal of heavy metals and reactive dyes in water. Environmental Pollution, 346:123637.

[50]MuZH, LiuDN, LvJ, et al., 2022. Insight into the highly efficient adsorption towards cationic methylene blue dye with a superabsorbent polymer modified by esterified starch. Journal of Environmental Chemical Engineering, 10(5):108425.

[51]NizamT, KrishnanKA, JosephA, et al., 2024. Isotherm, kinetic and thermodynamic modelling of liquid phase adsorption of the heavy metal ions Zn(II), Pb(II) and Cr(VI) onto MgFe₂O₄ nanoparticles. Groundwater for Sustainable Development, 25:101120.

[52]PatelH, 2021. Review on solvent desorption study from exhausted adsorbent. Journal of Saudi Chemical Society, 25(8):101302.

[53]QinXM, BaiL, TanYZ, et al., 2019. β‍-cyclodextrin-crosslinked polymeric adsorbent for simultaneous removal and stepwise recovery of organic dyes and heavy metal ions: fabrication, performance and mechanisms. Chemical Engineering Journal, 372:1007-1018.

[54]SahuS, BishoyiN, SahuMK, et al., 2021. Investigating the selectivity and interference behavior for detoxification of Cr(VI) using lanthanum phosphate polyaniline nanocomposite via adsorption-reduction mechanism. Chemosphere, 278:130507.

[55]SangorFIMS, Al-GhoutiMA, 2023. Waste-to-value: synthesis of nano-aluminum oxide (nano-γ-Al₂O₃) from waste aluminum foils for efficient adsorption of methylene blue dye. Case Studies in Chemical and Environmental Engineering, 8:100394.

[56]SelimAQ, MohamedEA, MobarakM, et al., 2018. Cr(VI) uptake by a composite of processed diatomite with MCM-41: isotherm, kinetic and thermodynamic studies. Microporous and Mesoporous Materials, 260:84-92.

[57]SemwalN, MaharD, ChattiM, et al., 2023. Adsorptive removal of Congo red dye from its aqueous solution by Ag-Cu-CeO₂ nanocomposites: adsorption kinetics, isotherms, and thermodynamics. Heliyon, 9(11):e22027.

[58]SongYL, WangLJ, QiangX, et al., 2023. An overview of biological mechanisms and strategies for treating wastewater from printing and dyeing processes. Journal of Water Process Engineering, 55:104242.

[59]SutarS, JadhavJ, 2024. A comparative assessment of the methylene blue dye adsorption capacity of natural biochar versus chemically altered activated carbons. Bioresource Technology Reports, 25:101726.

[60]TangJ, ZhangYF, LiuY, et al., 2020. Efficient ion-enhanced adsorption of Congo red on polyacrolein from aqueous solution: experiments, characterization and mechanism studies. Separation and Purification Technology, 252:117445.

[61]TattibayevaZ, TazhibayevaS, KujawskiW, et al., 2022. Peculiarities of adsorption of Cr (VI) ions on the surface of Chlorella vulgaris ZBS1 algae cells. Heliyon, 8(9):e10468.

[62]TranCC, DongHC, TruongVTN, et al., 2022. Enhancing the remarkable adsorption of Pb²⁺ in a series of sulfonic-functionalized Zr-based MOFs: a combined theoretical and experimental study for elucidating the adsorption mechanism. Dalton Transactions, 51(19):7503-7516.

[63]VisaM, BogatuC, DutaA, 2010. Simultaneous adsorption of dyes and heavy metals from multicomponent solutions using fly ash. Applied Surface Science, 256(17):‍5486-5491.

[64]WangD, ChenHS, XinCY, et al., 2024. Insight into adsorption of Pb(II) with wild resistant bacteria TJ6 immobilized on biochar composite: roles of bacterial cell and biochar. Separation and Purification Technology, 331:125660.

[65]WangJ, GaoML, ShenT, et al., 2019. Insights into the efficient adsorption of rhodamine B on tunable organo-vermiculites. Journal of Hazardous Materials, 366:‍‍501-511.

[66]WangSB, AriyantoE, 2007. Competitive adsorption of malachite green and Pb ions on natural zeolite. Journal of Colloid and Interface Science, 314(1):25-31.

[67]WangT, LiuW, XiongL, et al., 2013. Influence of pH, ionic strength and humic acid on competitive adsorption of Pb(II), Cd(II) and Cr(III) onto titanate nanotubes. Chemical Engineering Journal, 215-216:366-374.

[68]WangY, YuS, YuanHW, et al., 2024. Constructing N,S co-doped network biochar confined CoFe₂O₄ magnetic nanoparticles adsorbent: insights into the synergistic and competitive adsorption of Pb²⁺ and ciprofloxacin. Environmental Pollution, 343:123178.

[69]WuSJ, LiMY, XinLL, et al., 2022. Efficient removal of Cr(VI) by triethylenetetramine modified sodium alginate/carbonized chitosan composite via adsorption and photocatalytic reduction. Journal of Molecular Liquids, 366:120160.

[70]WuZD, WangXM, YaoJ, et al., 2021. Synthesis of polyethyleneimine modified CoFe₂O₄-loaded porous biochar for selective adsorption properties towards dyes and exploration of interaction mechanisms. Separation and Purification Technology, 277:119474.

[71]XieWJ, PakdelE, LiangYJ, et al., 2020. Natural melanin/TiO₂ hybrids for simultaneous removal of dyes and heavy metal ions under visible light. Journal of Photochemistry and Photobiology A: Chemistry, 389:112292.

[72]XieXM, LiaoM, XuN, et al., 2021. A Mixed Bacterial Agent for Degrading Mixed Wastewater of Toluene, Xylene, and Acrylic Acid Water and Its Applications. CN Patent 110591984 B(in Chinese).

[73]YangW, KongYD, YinH, et al., 2023. Study on the adsorption performance of ZIF-8 on heavy metal ions in water and the recycling of waste ZIF-8 in cement. Journal of Solid State Chemistry, 326:124217.

[74]YeWY, YeKF, LinF, et al., 2020a. Enhanced fractionation of dye/salt mixtures by tight ultrafiltration membranes via fast bio-inspired co-deposition for sustainable textile wastewater management. Chemical Engineering Journal, 379:122321.

[75]YeWY, LiuRR, ChenXY, et al., 2020b. Loose nanofiltration-based electrodialysis for highly efficient textile wastewater treatment. Journal of Membrane Science, 608:118182.

[76]YeWY, YuF, YuZJ, et al., 2024. High-performance antibacterial tight ultrafiltration membrane constructed by co-deposition of dopamine and tobramycin for sustainable high-salinity textile wastewater management. Desalination, 579:117482.

[77]ZhangQY, WangX, ChenHB, et al., 2023. Eco-friendly and magnetic sucrose-derived Fe-containing mesoporous carbon composites for high-efficiency Congo red adsorption and supercapacitor applications. Diamond and Related Materials, 139:110268.

[78]ZhangYB, ZhangL, WangNN, et al., 2023. Citric acid modified β‍-cyclodextrin for the synthesis of water-stable and recoverable CD-MOF with enhanced adsorption sites: efficient removal of Congo red and copper ions from wastewater. Journal of Environmental Chemical Engineering, 11(6):111413.