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[1]K.X. Wei, A. Armutulu, Y.X. Wang, G. Yao, R.Z. Xie*,B. Lai*,Visible-light-driven removal of atrazine by durable hollow core-shell TiO2@LaFeO3 heterojunction coupling with peroxymonosulfate via enhanced electron-transfer.Appl. Catal. B: Environ. (2022) 120889.
[2]M.F. Luo, H.Y. Zhou, P. Zhou, L.D. Lai, W. Liu, Z.M. Ao, G. Yao, H. Zhang*,B. Lai*,Metal-free Black-red Phosphorus as an Efficient Heterogeneous Reductant to Boost Fe3+/Fe2+ Cycle for Peroxymonosulfate Activation.Water Res.,188 (2021) 116529.
[3]H.Y. Zhou, J.L. Peng, J.Y. Li, J.J. You, L.D. Lai, R. Liu, Z.M. Ao, G. Yao,B. Lai*,Insights into the role of in-situ and ex-situ hydrogen peroxide for enhanced ferrate (VI) towards oxidation of organic contaminants.Water Res.,203(2021) 117548.
[4]J.L. Peng, P. Zhou, H.Y. Zhou, W. Liu, H. Zhang, C.Y. Zhou, L.D. Lai, Z.M. Ao, S.J. Su,B. Lai*,Insights into the Electron-Transfer Mechanism of Permanganate Activation by Graphite for Enhanced Oxidation of Sulfamethoxazole.Environ. Sci. Tech.,55 (2021) 9189-9198.
[5]J.Y. Li, Z.K. Xiong*, Y.H. Yu, X.H. Wang, H.Y. Zhou, B.K. Huang, Z.L. Wu, C.X. Yu, T.T. Chen, Z.C. Pan, G. Yao,B. Lai*,Efficient degradation of carbamazepine by electro-Fenton system without any extra oxidant in the presence of molybdate: The role of slow release of iron ions.Appl. Catal. B: Environ.298 (2021) 120506.
[6]L.D. Lai, P. Zhou, H.Y. Zhou, M.L. Sun, Y. Yuan, Y. Liu, G. Yao,B. Lai*,Heterogeneous Fe(III)/Fe(II) circulation in FeVO4 by coupling with dithionite towards long-lasting peroxymonosulfate activation: Pivotal role of vanadium as electron shuttles.Appl. Catal. B: Environ.297 (2021) 120470.
[7]L.D. Lai, H.D. Ji, H. Zhang, R. Liu, C.Y. Zhou, W. Liu, Z.M. Ao, N.W. Li, C. Liu*, G. Yao,B. Lai*, Activation of Peroxydisulfate by V-Fe Concentrate Ore for Enhanced Degradation of Carbamazepine: Surface ≡V(III) and ≡V(IV) as Electron Donors Promoted the Regeneration of ≡Fe(II).Appl. Catal. B: Environ.282 (2021) 119559
[8]H.Y. Zhou, H. Zhang, Y.L. He, B.K. Huang, C.Y. Zhou, G. Yao,B. Lai*, Critical Review of Reductant-enhanced Peroxide Activation Process: Trade-off between Accelerated Fe3+/Fe2+ Cycle and Quenching Reactions.Appl. Catal. B: Environ.286 (2021) 119900.
[9]Y.D. Dong, H. Zhang, G.J. Zhong*, G. Yao,B. Lai*, Cellulose/carbon Composites and their Applications in Water Treatment-a Review,Chem. Eng. J., 405 (2021) 126980.
[10]Z.K. Xiong, J.Y. Li, Y. Li, Y. Yuan, Y.N. Jiang, G. Yao,B. Lai*, Simultaneously enhanced degradation of N, N-dimethylacetamide and reduced formation of iron sludge by an efficient electrolysis catalyzed ozone process in the presence of dissolved silicate.J. Hazard. Mater.,406 (2021) 124725.
[11]Z.L. Wu, Y.P. Wang, Z.K. Xiong*, Z.M. Ao, S.Y. Pu, G. Yao,B. Lai*, Core-shell magnetic Fe3O4@Zn/Co-ZIFs to activate peroxymonosulfate for highly efficient degradation of carbamazepine.Appl. Catal. B: Environ.277 (2020) 119136.
[12]Z.Y. Shen, H.Y. Zhou, Z.C. Pan, Y. Guo, Y. Yuan*, G. Yao,B. Lai*, Degradation of atrazine by Bi2MoO6 activated peroxymonosulfate under visible light irradiation,J. Hazard. Mater.,400 (2020) 123187.
[13]M.J. Xu, H.Y. Zhou, Z.L. Wu, N.W. Li*, Z.K. Xiong, G. Yao,B. Lai*, Efficient degradation of sulfamethoxazole by NiCo2O4modified expanded graphite activated peroxymonosulfate: Characterization, mechanism and degradation intermediates,J. Hazard. Mater.,399 (2020) 123103.
[14]F. Liu, H.Y. Zhou, Z.C. Pan, Y. Liu*, G. Yao, Y. Guo,B. Lai*, Degradation of sulfamethoxazole by cobalt-nickel powder composite catalyst coupled with peroxymonosulfate: performance, degradation pathways and mechanistic consideration,J. Hazard. Mater.,400 (2020) 123322.
[15]Y.H. Zhang, L. Wang, Z.K. Xiong, W.G. Wang, D. Zheng, T. He, Y. Liu, Y. Ran, L.W. Deng*,B. Lai*, Removal of antibiotic resistance genes from post-treated swine wastewater by mFe/nCu system,Chem. Eng. J., 400 (2020) 125953.
[16]J.J. You, W.Y. Sun, S.J. Shu, Z.M. Ao, C. Liu*, G. Yao,B. Lai*, Degradation of bisphenol A by peroxymonosulfate activated with oxygen vacancy modified nano-NiO-ZnO composite oxides: A typical surface-bound radical system,Chem. Eng. J., 400 (2020) 125915.
[17]J.L. Peng, H.Y. Zhou, W. Liu, Z.M. Ao, H.D. Ji, Y. Liu*, S.J. Su, G. Yao,B. Lai*, Insights into heterogeneous catalytic activation of peroxymonosulfate by natural chalcopyrite: pH-dependent radical generation, degradation pathway and mechanism,Chem. Eng. J., 397 (2020) 125387.
[18]Y.L. He, J.L. Zhang, H.Y. Zhou, G. Yao,B. Lai*, Synergistic multiple active species for the degradation of sulfamethoxazole by peroxymonosulfate in the presence of CuO-Fe0,Chem. Eng. J., 380 (2020) 122568.
[19]Y.C. Hong, H.Y. Zhou, Z.K. Xiong*, Y. Liu, G. Yao,B. Lai*, Heterogeneous activation of peroxymonosulfate by CoMgFe-LDO for degradation of carbamazepine: Efficiency, mechanism and degradation pathways,Chem. Eng. J., (2020) 123604.
[20]Y.J. Li, J. Li, Y.T. Pan, Z.K. Xiong*, G. Yao, R.Z. Xie,B. Lai*, Peroxymonosulfate activation on FeCo2S4 modified g-C3N4(FeCo2S4-CN): Mechanism of singlet oxygen evolution for nonradical efficient degradation of sulfamethoxazole,Chem. Eng. J., 384 (2020) 123361.
[21]J.L. Zhang, Z.K. Xiong, J. Wei*, Y.H. Song, Y.Z. Ren, D.Y. Xu,B. Lai*, Catalytic ozonation of penicillin G using cerium-loaded natural zeolite (CZ): Efficacy, mechanisms, pathways and toxicity assessment,Chem. Eng. J., 383 (2020) 123144.
[22]H.Y. Zhou, L.D. Lai, Y.J. Wan, Y.L. He, G. Yao,B. Lai*, Molybdenum disulfide (MoS2): A versatile activator of both peroxymonosulfate and persulfate for the degradation of carbamazepine,Chem. Eng. J., 384 (2020) 123264.
[23]L.D. Lai, H.Y. Zhou, H. Zhang, Z.M. Ao, Z.C. Pan, Q.X. Chen, Z.K. Xiong*, G. Yao,B. Lai*, Activation of peroxydisulfate by natural titanomagnetite for atrazine removal via free radicals and high-valent iron-oxo species,Chem. Eng. J., 387 (2020) 124165.
[24]Z.K. Xiong, H. Zhang, W.C. Zhang,B. Lai*, G. Yao, Removal of nitrophenols and their derivatives by chemical redox: A review,Chem. Eng. J.,359 (2019) 13-31.
[25]J.F. Yan, J. Li, J.L. Peng, H. Zhang, Y.H. Zhang,B. Lai*, Efficient degradation of sulfamethoxazole by the CuO@Al2O3(EPC) coupled PMS system: optimization, degradation pathways and toxicity evaluation,Chem. Eng. J.,359 (2019) 1097-1110.
[26]F.Z. Ji, H. Zhang, X.X. Wei, Y.H. Zhang,B. Lai*, Efficient degradation of atrazine by Co-NZ catalyst prepared by electroless plating in the presence of peroxymonosulfate: Characterization, performance and mechanistic consideration,Chem. Eng. J.,359 (2019) 1316-1326.
[27]J. Li, J.F. Yan, G. Yao, Y.H., Zhang,B. Lai*, Improvement the degradation of atrazine in aqueous solution by CuFe2O4 as both particle electrode and catalyst for persulfate activation,Chem. Eng. J.,361 (2019) 1317-1332.
[28]M.J. Xu, J. Li, Y. Yan, X.G. Zhao, J.F. Yan, Y.H. Zhang,B. Lai*, X. Chen, L.P. Song, Catalytic degradation of sulfamethoxazole through peroxymonosulfate activated with expanded graphite loaded CoFe2O4particles,Chem. Eng. J.,369 (2019) 403-413.
[29]R.J. Zhang, Y.J. Wan, J.L. Peng, G. Yao, Y.H. Zhang,B. Lai*, Efficient degradation of atrazine by LaCoO3/Al2O3catalyzed peroxymonosulfate: Performance, degradation intermediates and mechanism,Chem. Eng. J.,372 (2019) 796-808.
[30]J.Y. Cao, L.D. Lai,B. Lai*, G. Yao, X. Chen, L.P. Song,Degradation of tetracycline by peroxymonosulfate activated with zero-valent iron: performance, intermediates, toxicity and mechanism,Chem. Eng. J.,364 (2019) 45-56.
[31]Y.C. Hong, J.L. Peng, X.G. Zhao, Y. Yan,B. Lai*, G. Yao,Efficient degradation of atrazine by CoMgAl layered double oxides catalyzed peroxymonosulfate: Optimization, degradation pathways and mechanism,Chem. Eng. J.,370 (2019)354-363
[32]Y.J. Li, X.G. Zhao, Y. Yan, J.F. Yan, Y.T. Pan, Y.H. Zhang,B. Lai*, Enhanced sulfamethoxazole degradation by peroxymonosulfate activation with sulfide-modified microscale zero-valent iron (S-mFe0): Performance, mechanisms, and the role of sulfur species,Chem. Eng. J.,376 (2019) 121302.
[33]J. Li, Y.J. Wan, Y.J. Li, G. Yao,B. Lai*, Surface Fe(III)/Fe(II) cycle promoted the degradation of atrazine by peroxymonosulfate activation in the presence of hydroxylamine,Applied Catalysis B: Environmental,256 (2019) 117782.
[34]Z.K. Xiong,B. Lai*, P. Yang, Insight into a highly efficient electrolysis-ozone process for N,N -dimethylacetamide degradation: Quantitative analysis of the role of catalytic ozonation, fenton-like and peroxone reactions,Water Res.,140 (2018)12-23.
[35]J.F. Yan, J.L. Peng, L.D. Lai, F.Z. Ji, Y.H. Zhang,B. Lai*, Q.X. Chen, G. Yao, X. Chen, L.P. Song, Activation CuFe2O4by Hydroxylamine for Oxidation of Antibiotic Sulfametheoxazole,Environ. Sci. Tech.,52 (2018)14302-14310.
[36]J. Li, M.J. Xu, G. Yao,B. Lai*, Enhancement of the degradation of atrazine through CoFe2O4activated peroxymonosulfate (PMS) process: kinetic, degradation intermediates, and toxicity evaluation,Chem. Eng. J.,348 (2018) 1012-1024.
[37]L.D. Lai, H.Y. Zhou,B. Lai*,Heterogeneous degradation of bisphenol A by peroxymonosulfate activated with vanadium-titanium magnetite: Performance, transformation pathways and mechanism.Chem. Eng. J.,349 (2018) 633-645.
[38]J. Li, Y. Ren, L.D. Lai,B. Lai*, Electrolysis assisted persulfate with annular iron sheet as anode for the enhanced degradation of 2, 4-dinitrophenol in aqueous solution.J. Hazard. Mater.,344 (2018) 778-787.
[39]L.D. Lai, J.F. Yan, J. Li,B. Lai*, Co/Al2O3-EPM asperoxymonosulfate activator forsulfamethoxazole removal: Performance, biotoxicity, degradation pathways and mechanism.Chem. Eng. J.,343 (2018) 676-688.
[40]J.Y. Cao, Z.K. Xiong,B. Lai*, Effect of initial pH on the tetracycline (TC) removal by zero-valent iron: adsorption, oxidation and reduction.Chem. Eng. J.,343 (2018) 492-499.
[41]J.L. Peng, X.H. Lu, X. Jiang, Y.H. Zhang, G. Yao,B. Lai*, Degradation of atrazine by persulfate activation with copper sulfide (CuS): Kinetics study, degradation pathways and mechanism.Chem. Eng. J.,354 (2018) 740-752.
[42]J. Li, Q. Liu, Q.Q. Ji,B. Lai*,Degradation ofp-nitrophenol (PNP) in aqueous solution by Fe0-PM-PS system through response surface methodology (RSM).Appl. Catal. B: Environ.200 (2017) 633-646.
[43]J. Li, Y. Ren, F.Z. Ji,B. Lai*, Heterogeneous catalytic oxidation for the degradation ofp-nitrophenol in aqueous solution by persulfate activated with CuFe2O4magnetic nano-particles.Chem. Eng. J.,324 (2017) 63-73.
[44]Y. Ren, J.H. Yang, J. Li,B. Lai*, Strengthening the reactivity of Fe0/(Fe/Cu) by premagnetization: implications for selectivity and rate for nitrate reduction.Chem. Eng. J.,330 (2017) 813-822.
[45]Y. Yuan,B. Lai*, Y.Y. Tang,Combined Fe0/air and Fenton process for the treatment of dinitrodiazophenol (DDNP) industry wastewater.Chem. Eng. J., 283 (2016)1514-1521.
[46]Y. Ren, Y. Yuan,B. Lai*, Y.X. Zhou, J.L. Wang,Treatment of reverse osmosis (RO) concentrate by the combined Fe/Cu/air and Fenton process (1stFe/Cu/air-Fenton-2ndFe/Cu/air).J. Hazard. Mater., 302 (2016) 36-44.
[47]Q.Q. Ji,Y. Yuan,B. Lai*, P. Yang, Y.X. Zhou,Pretreatment of ultra-high concentration wastewater from halogen-free flame retardant resin manufacturing by chemical precipitation, reduction and oxidation.J. Hazard. Mater., 308 (2016) 276-284.
[48]Z.K. Xiong, Y. Yuan,B. Lai*, P. Yang, Y.X. Zhou,Degradation ofp-nitrophenol (PNP) in aqueous solution bya novel micro-sizeFe0/O3process (mFe0/O3): Optimization, kinetic, performance and mechanism,Chem. Eng. J.302 (2016) 137-145.
[49]Z.K. Xiong,B. Lai*, P. Yang, Y.X. Zhou, J.L. Wang, S.P. Fang,Comparative study on the reactivity of Fe/Cu bimetallic particles and zero valent iron (ZVI) under different conditions of N2, air or without aeration.J. Hazard. Mater., 297 (2015) 261-268.
[50]B. Lai*, Y.H. Zhang, Z.Y. Chen, P. Yang, Y.X. Zhou, J.L. Wang,Removal ofp-nitrophenol (PNP) in aqueous solution by themicron-scale iron-copper (Fe/Cu) bimetallic particles.Appl. Catal. B: Environ.144 (2014) 816-830.