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第 1 期陈冠益，等: 污泥生物炭基催化剂在高级氧化水处理的应用 ·55·

Technology, 2016, 214: 836-851. [41] ZHU S J, WANG W, XU Y P, et al. Iron sludge-derived magnetic
0
[29] LI J, DAI J J, LIU G Q, et al. Biochar from microwave pyrolysis of Fe /Fe 3C catalyst for oxidation of ciprofloxacin via peroxymonosulfate
biomass: A review [J]. Biomass and Bioenergy, 2016, 94: 228-244. activation[J]. Chemical Engineering Journal, 2019, 365: 99-110.
[30] YU Y, YU J Q, SUN B, et al. Influence of catalyst types on the [42] DIAO Z H, DONG F X, YAN L, et al. Synergistic oxidation of
microwave-induced pyrolysis of sewage sludge[J]. Journal of Analytical bisphenol A in a heterogeneous ultrasound-enhanced sludge biochar
and Applied Pyrolysis, 2014, 106: 86-91. catalyst/persulfate process: Reactivity and mechanism[J]. Journal of
[31] SUN S C, HUANG X F, LIN J H, et al. Study on the effects of Hazardous Materials, 2020, 384: 121385.
catalysts on the immobilization efficiency and mechanism of heavy [43] ZHU F, WU Y Y, LIANG Y K, et al. Degradation mechanism of
metals during the microwave pyrolysis of sludge[J]. Waste Management, norfloxacin in water using persulfate activated by BC@nZVI/Ni[J].
2018, 77: 131-139. Chemical Engineering Journal, 2020, 389: 124276.
[32] MIAN M M, LIU G. Activation of peroxymonosulfate by chemically [44] WANG S Z, WANG J L. Peroxymonosulfate activation by Co 9S 8@S
modified sludge biochar for the removal of organic pollutants: and N co-doped biochar for sulfamethoxazole degradation[J].
Understanding the role of active sites and mechanism[J]. Chemical Chemical Engineering Journal, 2020, 385: 123933.
Engineering Journal, 2020, 392: 123681. [45] HE W Z, ZHU Y, ZENG G M, et al. Efficient removal of
[33] MATOS J, ROSALES M, GARCIA A, et al. Hybrid photoactive perfluorooctanoic acid by persulfate advanced oxidative degradation:
materials from municipal sewage sludge for the photocatalytic Inherent roles of iron-porphyrin and persistent free radicals[J].
degradation of methylene blue[J]. Green Chemistry, 2011, 13: 3431- Chemical Engineering Journal, 2020, 392: 123640.
3439. [46] HUANG B C, JIANG J, HUANG G X, et al. Sludge biochar-based
[34] YUAN S J, LI X W, DAI X H. Efficient degradation of organic catalysts for improved pollutant degradation by activating
pollutants with a sewage sludge support and in situ doped TiO 2 under peroxymonosulfate[J]. Journal of Materials Chemistry A, 2018, 6:
visible light irradiation conditions[J]. RSC Advances, 2014, 4: 61036- 8978-8985.
61044. [47] HU W R, TONG W H, LI Y L, et al. Hydrothermal route-enabled
[35] MIAN M M, LIU G J. Sewage sludge-derived TiO 2/Fe/Fe 3C-biochar synthesis of sludge-derived carbon with oxygen functional groups for
composite as an efficient heterogeneous catalyst for degradation of bisphenol A degradation through activation of peroxymonosulfate[J].
methylene blue[J]. Chemosphere, 2019, 215: 101-114. Journal of Hazardous Materials, 2020, 388: 121801.
[36] FENG B L (冯柏林), LIANG J M (梁继美), DU T (杜婷), et al. [48] CHEN Y D, DUAN X G, ZHANG C F, et al. Graphitic biochar
Study on the reaction mechanism of Fenton method and the catalysts from anaerobic digestion sludge for nonradical degradation
application of Fenton-type methods[J]. Guangdong Chemical Industry of micropollutants and disinfection[J]. Chemical Engineering Journal,
(广东化工), 2012, 39(15): 21-22, 26. 2020, 384: 123244.
[37] LI J, PAN L J, YU G W, et al. The synthesis of heterogeneous [49] YIN R L, GUO W Q, WANG H Z, et al. Singlet oxygen-dominated
Fenton-like catalyst using sewage sludge biochar and its application peroxydisulfate activation by sludge-derived biochar for sulfamethoxazole
for ciprofloxacin degradation[J]. Science of the Total Environment, degradation through a nonradical oxidation pathway: Performance
2019, 654: 1284-1292. and mechanism[J]. Chemical Engineering Journal, 2019, 357: 589-599.
[38] GAN Q, HOU H J, LIANG S, et al. Sludge-derived biochar with [50] MIAN M M, LIU G J, FU B, et al. Facile synthesis of sludge-derived
multivalent iron as an efficient Fenton catalyst for degradation of MnO x-N-biochar as an efficient catalyst for peroxymonosulfate
4-chlorophenol[J]. Science of the Total Environment, 2020, 725: activation[J]. Applied Catalysis B: Environmental, 2019, 255: 117765.
138299. [51] LI Y, YANG Z Q, ZHANG H G, et al. Fabrication of sewage
[39] HUANG Y F, HUANG Y Y, CHIUEH P T, et al. Heterogeneous sludge-derived magnetic nanocomposites as heterogeneous catalyst
Fenton oxidation of trichloroethylene catalyzed by sewage sludge for persulfate activation of orange G degradation[J]. Colloids and
biochar: Experimental study and life cycle assessment[J]. Chemosphere, Surfaces A: Physicochemical and Engineering Aspects, 2017, 529:
2020, 249: 126139. 856-863.
[40] WANG W G (王文刚), TAO H (陶红), DAI X H (戴晓虎). [52] PAN X Q, GU Z P, CHEN W M, et al. Preparation of biochar and
Dewatered sludge derived iron-carbon composite as a photo-Fenton biochar composites and their application in a Fenton-like process for
catalyst for organic pollutant degradation[J]. Chinese Journal of wastewater decontamination: A review[J]. Science of The Total
Environmental Engineering (环境工程学报), 2020, 14(8): 2232-2241. Environment, 2021, 754: 142104.

（上接第 16 页） characterization and catalytic effect in green oxidation of alcohols[J].
[59] ÁLVAREZ M G, URDĂ A, RIVES V, et al. Propane oxidative Polyhedron, 2015, 99: 260-265.
dehydrogenation over V-containing mixed oxides derived from [64] SANTOS O S, MASCARENHAS A J S, ANDRADE H M C.
decavanadate-exchanged ZnAl-layered double hydroxides prepared N 2O-assisted methanol selective oxidation to formaldehyde on cobalt
by a sol-gel method[J]. Comptes Rendus Chimie, 2018, 21(3/4): 210-220. oxide catalysts derived from layered double hydroxides[J]. Catalysis
[60] GAO X X, WANG J, XU A J, et al. Oxidative dehydrogenation of Communications, 2018, 113: 32-35.
propane over Ni-Al mixed oxides: Effect of the preparation methods [65] CESAR D V, BALDANZA M A S, HENRIQUES C A, et al. Stability
on the activity of surface Ni(Ⅱ) species[J]. Catalysis Letters, 2020, of Ni and Rh-Ni catalysts derived from hydrotalcite-like precursors
151(2): 497-506. for the partial oxidation of methane[J]. International Journal of
[61] SMOLÁKOVÁ L, ČAPEK L, BOTKOVÁ Š, et al. Activity of the Hydrogen Energy, 2013, 38(14): 5616-5626.
Ni-Al mixed oxides prepared from hydrotalcite-like precursors in the [66] HUANG L H, ZHOU J, HSU A T, et al. Catalytic partial oxidation of
oxidative dehydrogenation of ethane and propane[J]. Topics in n-butanol for hydrogen production over LDH-derived Ni-based
Catalysis, 2011, 54(16/17/18): 1151-1162. catalysts[J]. International Journal of Hydrogen Energy, 2013, 38(34):
[62] MITRAN G, URDA A, TANCHOUX N, et al. Propane oxidative 14550-14558.
dehydrogenation over Ln-Mg-Al-O catalysts (Ln = Ce, Sm, Dy, [67] JIA Y Q (贾岳清). Preparation and properties of polyoxometalate
Yb)[J]. Catalysis Letters, 2009, 131(1/2): 250-257. intercalated layered double hydroxides catalytic materials[D].
[63] HASANNIA S, YADOLLAHI B. Zn-Al LDH nanostructures pillared Beijing: Beijing University of Chemical Technology (北京化工大
by Fe substituted Keggin type polyoxometalate: Synthesis, 学), 2015.

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