Adsorption, separation and recovery performance of spherical PR/ CMC/AC composites for cadmium-contaminated soil remediation

doi:10.1016/j.cjche.2025.03.003

Abstract

Abstract: Activated carbon (AC) is considered to be an excellent adsorbent due to its high specific surface area and various functional groups. AC powders are available in sizes ranging from 44 to 150 mm. Its particle size prevent its separation from the soil. Therefore, when AC powder is applied to Cd-contaminated soil, it only reduces the bioavailability of Cd and Cd is not necessarily removed but semi-immobilized. Recovery of adsorbent materials from the soil is therefore a preferred soil remediation method. In order to achieve the separation of Cd from soil and the recovery and reuse of AC, a batch of phenolic resin (PR) -carboxymethyl cellulose (CMC)-activated carbon (AC) composite (PCC-800) with uniform particle diameter (diameter 0.8 mm) and high compressive strength was prepared. PCC-800 composites were made of PR/ CMC/AC calcined at 800 ℃ in a certain ratio. The Barrett Joyner Halender results showed that the PCC- 800 spheres own a mesoporous structure. The compressive strength of PCC-800 pellets was 20.6 N. After first adsorption cycle, total Cd in the soil decreased by 52.18% while bioavailable Cd decreased to 25.68% of the original soil. After three cycles, the recovery rates of PCC-800 were 90.37% and the adsorption regeneration was 72.73%. The PCC-800 immobilized Cd by adsorption, precipitation and complexation reaction. This study demonstrates the potential for developing adsorbents that are both easily separable from soil and highly effective in adsorption.

Key words: Cd, Spherical activated carbon composites, Adsorption, Recovery

摘要： Activated carbon (AC) is considered to be an excellent adsorbent due to its high specific surface area and various functional groups. AC powders are available in sizes ranging from 44 to 150 mm. Its particle size prevent its separation from the soil. Therefore, when AC powder is applied to Cd-contaminated soil, it only reduces the bioavailability of Cd and Cd is not necessarily removed but semi-immobilized. Recovery of adsorbent materials from the soil is therefore a preferred soil remediation method. In order to achieve the separation of Cd from soil and the recovery and reuse of AC, a batch of phenolic resin (PR) -carboxymethyl cellulose (CMC)-activated carbon (AC) composite (PCC-800) with uniform particle diameter (diameter 0.8 mm) and high compressive strength was prepared. PCC-800 composites were made of PR/ CMC/AC calcined at 800 ℃ in a certain ratio. The Barrett Joyner Halender results showed that the PCC- 800 spheres own a mesoporous structure. The compressive strength of PCC-800 pellets was 20.6 N. After first adsorption cycle, total Cd in the soil decreased by 52.18% while bioavailable Cd decreased to 25.68% of the original soil. After three cycles, the recovery rates of PCC-800 were 90.37% and the adsorption regeneration was 72.73%. The PCC-800 immobilized Cd by adsorption, precipitation and complexation reaction. This study demonstrates the potential for developing adsorbents that are both easily separable from soil and highly effective in adsorption.

关键词: Cd, Spherical activated carbon composites, Adsorption, Recovery

Fan Zhang, Miaomiao Zhao, Xiaoyu Jia, Chen Li, Degang Ma. Adsorption, separation and recovery performance of spherical PR/ CMC/AC composites for cadmium-contaminated soil remediation[J]. Chinese Journal of Chemical Engineering, 2025, 83(7): 199-207.

References

[1] L. Liu, S.S. Fan, Removal of cadmium in aqueous solution using wheat straw biochar: effect of minerals and mechanism, Environ. Sci. Pollut. Res. Int. 25(9) (2018) 8688-8700.
[2] Y.L. Liu, H.Y. Luo, B.Q. Tie, D.Y. Li, S.T. Liu, M. Lei, H.H. Du, The long-term effectiveness of ferromanganese biochar in soil Cd stabilization and reduction of Cd bioaccumulation in rice, Biochar 3(4) (2021) 499-509.
[3] F.J. Zhao, Y.B. Ma, Y.G. Zhu, Z. Tang, S.P. McGrath, Soil contamination in China: current status and mitigation strategies, Environ. Sci. Technol. 49(2) (2015) 750-759.
[4] Y.C. Wang, A. Li, C.W. Cui, Remediation of heavy metal-contaminated soils by electrokinetic technology: mechanisms and applicability, Chemosphere 265(2021) 129071.
[5] G. Dermont, M. Bergeron, G. Mercier, M. Richer-Lafleche, Soil washing for metal removal: a review of physical/chemical technologies and field applications, J. Hazard Mater. 152(1) (2008) 1-31.
[6] G.R. Qian, W. Chen, T.T. Lim, P. Chui, In-situ stabilization of Pb, Zn, Cu, Cd and Ni in the multi-contaminated sediments with ferrihydrite and apatite composite additives, J. Hazard Mater. 170(2-3) (2009) 1093-1100.
[7] T.T. Qian, P. Wu, Q.Y. Qin, Y.N. Huang, Y.J. Wang, D.M. Zhou, Screening of wheat straw biochars for the remediation of soils polluted with Zn (II) and Cd (II), J. Hazard Mater. 362(2019) 311-317.
[8] Y. Li, T. Xie, Y. Zha, W. Du, Y. Yin, H. Guo, Urea-enhanced phytoremediation of cadmium with willow in pyrene and cadmium contaminated soil, J. Hazard Mater. 405(2021) 124257.
[9] N. Bolan, A. Kunhikrishnan, R. Thangarajan, J. Kumpiene, J. Park, T. Makino, M. B. Kirkham, K. Scheckel, Remediation of heavy metal(loid)s contaminated soils: to mobilize or to immobilize? J. Hazard Mater. 266(2014) 141-166.
[10] Y. Hamid, L. Tang, M.I. Sohail, X. Cao, B. Hussain, M.Z. Aziz, M. Usman, Z.L. He, X. Yang, An explanation of soil amendments to reduce cadmium phytoavailability and transfer to food chain, Sci. Total Environ. 660(2019) 80-96.
[11] J.T. Qiao, T.X. Liu, X.Q. Wang, F.B. Li, Y.H. Lv, J.H. Cui, X.D. Zeng, Y.Z. Yuan, C.P. Liu, Simultaneous alleviation of cadmium and arsenic accumulation in rice by applying zero-valent iron and biochar to contaminated paddy soils, Chemosphere 195(2018) 260-271.
[12] L.Z. He, H. Zhong, G.X. Liu, Z.M. Dai, P.C. Brookes, J.M. Xu, Remediation of heavy metal contaminated soils by biochar: mechanisms, potential risks and applications in China, Environ. Pollut. 252(Pt A) (2019) 846-855.
[13] W. Qian, J.Y. Liang, W.X. Zhang, S.T. Huang, Z.H. Diao, A porous biochar supported nanoscale zero-valent iron material highly efficient for the simultaneous remediation of cadmium and lead contaminated soil, J. Environ. Sci. (China) 113(2022) 231-241.
[14] F.F. Sui, J. Zuo, D. Chen, L.Q. Li, G.X. Pan, D.E. Crowley, Biochar effects on uptake of cadmium and lead by wheat in relation to annual precipitation: a 3-year field study, Environ. Sci. Pollut. Res. Int. 25(4) (2018) 3368-3377.
[15] H.B. Gong, Z.X. Tan, K. Huang, Y.Q. Zhou, J.H. Yu, Q.Y. Huang, Mechanism of cadmium removal from soil by silicate composite biochar and its recycling, J. Hazard Mater. 409(2021) 125022.
[16] Y.L. Liu, Y.D. Huang, C. Zhang, W.Y. Li, C.Y. Chen, Z. Zhang, H.Y. Chen, J.J. Wang, Y.T. Li, Y.L. Zhang, Nano-FeS incorporated into stable lignin hydrogel: a novel strategy for cadmium removal from soil, Environ. Pollut. 264(2020).
[17] G.C. Yin, X.W. Song, L. Tao, B. Sarkar, A.K. Sarmah, W.X. Zhang, Q.T. Lin, R.B. Xiao, Q.J. Liu, H.L. Wang, Novel Fe-Mn binary oxide-biochar as an adsorbent for removing Cd(II) from aqueous solutions, Chem. Eng. J. 389(2020) 124465.
[18] H.A. Murad, M. Ahmad, J. Bundschuh, Y. Hashimoto, M. Zhang, B. Sarkar, Y.S. Ok, A remediation approach to chromium-contaminated water and soil using engineered biochar derived from peanut shell, Environ. Res. 204(2022) 112125.
[19] C. Nair, Advances in addition-cure phenolic resins, Prog. Polym. Sci. 29(5) (2004) 401-498.
[20] X.H. Zou, J.M. Pan, H.X. Ou, X. Wang, W. Guan, C.X. Li, Y.S. Yan, Y.Q. Duan, Adsorptive removal of Cr(III) and Fe(III) from aqueous solution by chitosan/ attapulgite composites: equilibrium, thermodynamics and kinetics, Chem. Eng. J. 167(1) (2011) 112-121.
[21] R. Rusmin, B. Sarkar, Y.J. Liu, S. McClure, R. Naidu, Structural evolution of chitosan-palygorskite composites and removal of aqueous lead by composite beads, Appl. Surf. Sci. 353(2015) 363-375.
[22] S. Canzano, P. Iovino, S. Salvestrini, S. Capasso, Comment on removal of anionic dye Congo red from aqueous solution by raw pine and acid-treated pine cone powder as adsorbent: equilibrium, thermodynamic, kinetics, mechanism and process design, Water Res. 46(13) (2012) 431-4315.
[23] J. Liang, J.F. Liu, X.Z. Yuan, H.R. Dong, G.M. Zeng, H.P. Wu, H. Wang, J.Y. Liu, S.S. Hu, S.Q. Zhang, Z.G. Yu, X.X. He, Y. He, Facile synthesis of alumina-decorated multi-walled carbon nanotubes for simultaneous adsorption of cadmium ion and trichloroethylene, Chem. Eng. J. 273(2015) 101-110.
[24] L. Wang, C.L. Wan, D.J. Lee, X. Liu, Y. Zhang, X.F. Chen, J.H. Tay, Biosorption of antimony(V) onto Fe(III)-treated aerobic granules, Bioresour. Technol. 158(2014) 351-354.
[25] H.N. Tran, S.J. You, A. Hosseini-Bandegharaei, H.P. Chao, Mistakes and inconsistencies regarding adsorption of contaminants from aqueous solutions: a critical review, Water Res. 120(2017) 88-116.
[26] J.H. Qu, X.L. Meng, X.Y. Jiang, H. You, P. Wang, X.Q. Ye, Enhanced removal of Cd(II) from water using sulfur-functionalized rice husk: characterization, adsorptive performance and mechanism exploration, J. Clean. Prod. 183(2018) 880-886.
[27] J.E. Liang, X.M. Li, Z.G. Yu, G.M. Zeng, Y.A. Luo, L.B. Jiang, Z.X. Yang, Y.Y. Qian, H. P. Wu, Amorphous MnO₂ modified biochar derived from aerobically composted swine manure for adsorption of Pb(II) and Cd(II), ACS Sustain. Chem. Eng. 5(6) (2017) 5049-5058.
[28] P.Y. Liu, D.A. Rao, L.Y. Zou, Y. Teng, H.Y. Yu, Capacity and potential mechanisms of Cd(II) adsorption from aqueous solution by blue algae-derived biochars, Sci. Total Environ. 767(2021) 145447.
[29] L. Lin, W. Qiu, D. Wang, Q. Huang, Z. Song, H.W. Chau, Arsenic removal in aqueous solution by a novel FeeMn modified biochar composite: characterization and mechanism, Ecotoxicol. Environ. Saf. 144(2017) 514-521.
[30] K.J. Zou, J.F. Wei, D. Wang, Z.Y. Kong, H. Zhang, H.C. Wang, A novel remediation method of cadmium (Cd) contaminated soil: dynamic equilibrium of Cd2+ rapid release from soil to water and selective adsorption by PP-g-AA fibers-ball at low concentration, J. Hazard Mater. 416(2021) 125884.
[31] M.M. Zhao, D.G. Ma, Y. Y, Adsorption, separation and recovery properties of blocky zeolite-biochar composites for remediation of cadmium contaminated soil, Chin. J. Environ. 54(2023) 272-279.
[32] S.N. Yuan, J.Y. Zhang, Z.X. Tan, In-situ passivation mechanism of modified silicate composite biochar on soil cadmium, J. Environ. Chem. Eng. 10(2022) 109007.
[33] S.N. Yuan, J.Y. Zhang, Adsorption effect and the removal mechanism of silicate composite biochar particles on cadmium in soil, Chemosphere 303(2022) 134970.
[34] M.Y. Qian, M.C. Lu, M.J. Yan, C.F. Chen, Y.W. Hu, Y. Li, J.R. Chen, X.L. Wu, Singleatom Co-N3 sites supported on waste paper-derived active carbon for synergistic adsorption and catalytic degradation of antibiotics, J. Environ. Chem. Eng. 11(2023) 109219.
[35] J.C. Yoo, C.D. Lee, J.S. Yang, K. Baek, Extraction characteristics of heavy metals from marine sediments, Chem. Eng. J. 228(2013) 688-699.
[36] T.I.T. Okpalugo, P. Papakonstantinou, H. Murphy, J. McLaughlin, N.M.D. Brown, High resolution XPS characterization of chemical functionalised MWCNTs and SWCNTs, Carbon 43(1) (2005) 153-161.
[37] S.S. Wang, B. Gao, Y.C. Li, A. Mosa, A.R. Zimmerman, L.Q. Ma, W.G. Harris, K. W. Migliaccio, Manganese oxide-modified biochars: Preparation, characterization, and sorption of arsenate and lead, Bioresour. Technol. 181(2015) 13-17.
[38] O.R. Harvey, B.E. Herbert, R.D. Rhue, L.J. Kuo, Metal interactions at the biocharwater interface: Energetics and structure-sorption relationships elucidated by flow adsorption microcalorimetry, Environ. Sci. Technol. 45(13) (2011) 5550-5556.
[39] B.C. Qi, C. Aldrich, Biosorption of heavy metals from aqueous solutions with tobacco dust, Bioresour. Technol. 99(13) (2008) 5595-5601.