第 9 期             关桦楠，等:  基于芬顿反应纳米模拟酶快速去除水中有机污染物的应用进展                                   ·1743·


            [5]   HUANG  G T, HUANG L. Particulate copper electrodeposited on   [24]  LI W  B, WAN D, WANG  G  H,  et al.  Heterogeneous Fenton
                 carbon felt for degradation of low concentration of methyl iodide in   degradation of Orange  Ⅱ  by immobilization of Fe 3O 4 nanoparticles
                 liquid radioactive wastes[J].  Water Science and  Technology, 2019,   onto Al-Fe pillared bentonite[J]. Korean Journal of Chemical
                 80(3): 397-407.                                   Engineering, 2016, 33(5): 1557-1564.
            [6]   WU D D, BAI Y, WANG W, et al. Highly pure MgO 2 nanoparticles   [25]  CHEN S (陈思), BAI B (白波), WANG H  L (王洪伦),  et al.
                 as robust solid oxidant  for enhanced Fenton-like  degradation of   Preparation of prussian blue@yeast catalyst and its heterogeneous
                 organic contaminants[J]. Journal of Hazardous Materials, 2019, 374:   fenton performance[J]. Environmental Science (环境科学), 2018,
                 319-328.                                          39(8): 3759-3766.
            [7]   BAO  L J, MARUYA K  A, SNYDER S A,  et al.  China's water   [26]  SHI W, DU D, SHEN B,  et al.  Synthesis of yolk-shell  structured
                 pollution by persistent organic pollutants[J]. Environmental   Fe 3O 4@void@CdS nanoparticles:A general and effective structure
                 Pollution, 2012, 163: 100-108.                    design for photo-Fenton reaction[J]. ACS Applied Materials &
            [8]   RAY S K, DHAKAL  D,  GYAWALI G,  et al.  Transformation of   Interfaces, 2016, 8(32): 20831-20838.
                 tetracycline in water during degradation by visible light driven Ag   [27]  REN H J, SU Y,  HAN  X,  et al.  Synthesis and characterization of
                 nanoparticles decorated  α-NiMoO 4 nanorods: Mechanism  and   saponin-modified Fe 3O 4 nanoparticles as heterogeneous Fenton-
                 pathways[J]. Chemical Engineering Journal, 2019, 373: 259-274.     catalyst  with enhanced degradation of p-nitrophenol[J]. Journal of
            [9]   WU X P, NAN  Z D. Degradation of Rhodamine B by a novel   Chemical Technology & Biotechnology, 2017, 92(6): 1421-1427.
                 Fe 3O 4/SiO 2 double-mesoporous-shelled hollow spheres through   [28]  HUA Y N (华亚妮). Study on degradation of organic pollutants in
                 photo-Fenton  process[J]. Materials Chemistry and Physics, 2019,   polyphenol-Fe 3O 4  Fenton-like system[D].  Bejing: University of
                 227: 302-312.                                     Chinese Academy of Sciences (中国科学院大学), 2018.
            [10]  LI X  W, LIU  X  T, LIN C  Y,  et al.  Cobalt ferrite nanoparticles   [29]  VEISI H, MORADI S B, SALJOOQI A, et al. Silver nanoparticle-
                 supported on drinking water treatment residuals: An efficient   decorated on tannic acid-modified magnetite nanoparticles (Fe 3O 4@
                 magnetic heterogeneous catalyst to activate peroxymonosulfate for   TA/Ag) for highly active catalytic reduction  of  4-nitrophenol,
                 the degradation of atrazine[J]. Chemical Engineering Journal, 2019,   Rhodamine B  and Methylene Blue[J]. Materials Science and
                 367: 208-218.                                     Engineering: C, 2019, 100: 445-452.
            [11]  HUANG  X P, CHEN Y, WALTER E,  et al.  Facet-specific   [30]  SHI X G, TIAN A, YOU J H, et al. Degradation of organic dyes by a
                 photocatalytic degradation of organics by heterogeneous Fenton   new heterogeneous fenton reagent-Fe 2GeS 4 nanoparticle[J]. Journal
                 chemistry on hematite nanoparticles[J]. Environmental Science &   of Hazardous Materials, 2018, 353: 182-189.
                 Technology, 2019, 53(17): 10197-10207.        [31]  ZHANG J, CHEN M Y, ZHU L. Activation of persulfate by Co 3O 4
            [12]  LIAN J T, OUYANG Q, TSANG P  E,  et al.  Fenton-like catalytic   nanoparticles for  Orange G degradation[J]. RSC  Advances, 2016,
                 degradation of tetracycline by  magnetic palygorskite nanoparticles   6(1): 758-768.
                 prepared from steel pickling waste liquor[J]. Applied Clay Science,   [32]  SEHATI S,  ENTEZARI M H. Sono-incorporation of CuO
                 2019, 182: 105273.                                nanoparticles on the surface and into the mesoporous  hexatitanate
            [13]  WEI X R, ZHU N W, HUANG X X, et al. Efficient degradation of   layers: Enhanced Fenton-like activity in degradation of Orange-G at
                 sodium diclofenac  via  heterogeneous Fenton  reaction boosted by   its neutral pH[J]. Applied Surface Science, 2017, 399: 732-741.
                 Pd/Fe@Fe 3O 4 nanoparticles derived from bio-recovered palladium[J].   [33]  SOHRABNEZHAD S, MOOSHANGAIE S D. In situ fabrication of
                 Journal of Environmental Management, 2020, 260: 110072.     n-type Ag/AgBr nanoparticles in MCM-41 with rice husk
            [14]  XIANG Y B, HUANG Y H, XIAO B,  et al.  Magnetic yolk-shell   (RH/MCM-41) composite for the removal of Eriochrome Black-T[J].
                 structure of ZnFe 2O 4 nanoparticles for enhanced visible light   Materials Science and Engineering: B, 2019, 240: 16-22.
                 photo-Fenton degradation  towards  antibiotics and mechanism   [34]  GOGOI A, NAVGIRE M, SARMA  K C,  et al.  Highly efficient
                 study[J]. Applied Surface Science, 2020, 513: 145820.     heterogeneous Fenton activities of magnetic  β-cyclodextrin (Fe)
            [15]  CHEN C,  ZHANG S Y, ZHANG  C  W,  et al.  TMB-assembly as   framework for Eriochrome  Black  T degradation[J]. Materials
                 nanosubstrate construction colorimetric kit for highly sensitive and   Chemistry and Physics, 2019, 231: 233-243.
                 selective detection of H 2O 2 and monoamine oxidase-A based on   [35]  WAN J J, FENG X, LI Y, et al. Effect of mesoporous silica molecular
                 Fenton reaction[J]. Microchemical Journal, 2019, 150: 104177.     sieve coating on NZVI for 2, 4-DCP degradation: Morphology and
            [16]  DARWESH  O M, MATTER I A,  EIDA M F. Development of   mechanism during the reaction[J]. Chemical Engineering and
                 peroxidase enzyme immobilized magnetic nanoparticles for   Processing-Process Intensification, 2019, 135: 68-81.
                 bioremediation of textile wastewater dye[J]. Journal of   [36]  GONG Q  J, LIU  Y, DANG  Z. Core-shell  structured
                 Environmental Chemical Engineering, 2019, 7(1): 102805.     Fe 3O 4@GO@MIL-100(Fe) magnetic nanoparticles as heterogeneous
            [17]  HU J L, LU Q J, WU C Y, et al. Germanium nanoparticles: Intrinsic   photo-Fenton catalyst for 2, 4-dichlorophenol degradation under
                 peroxidase-like catalytic  activity and its biosensing application[J].   visible light[J]. Journal of Hazardous Materials, 2019, 371: 677-686.
                 Talanta, 2019, 195: 407-413.                  [37]  KERMANI M, KAKAVANDI B, FARZADKIA M,  et al. Catalytic
            [18]  BAO  Y W, HUA  X W, RAN  H  H,  et al.  Metal-doped carbon   ozonation  of high concentrations  of catechol over TiO 2@Fe 3O 4
                 nanoparticles with intrinsic peroxidase-like activity for colorimetric   magnetic core-shell nanocatalyst:  Optimization, toxicity and
                 detection of H 2O 2 and glucose[J]. Journal of Materials Chemistry B,   degradation pathway studies[J]. Journal of Cleaner Production, 2018,
                 2019, 7(2): 296-304.                              192: 597-607.
            [19]  SONG C, DING W, ZHAO W W, et al. High peroxidase-like activity   [38]  GOGOI  A,  NAVGIRE M, SARMA K C,  et al.  Fe 3O 4-CeO 2 metal
                 realized by facile synthesis of FeS 2 nanoparticles for sensitive   oxide nanocomposite as a Fenton-like heterogeneous catalyst for
                 colorimetric detection of H 2O 2  and glutathione[J]. Biosensors and   degradation of catechol[J]. Chemical Engineering Journal, 2017, 311:
                 Bioelectronics, 2020, 151: 111983.                153-162.
            [20]  DING Y N, YANG B C,  LIU H,  et al.  FePt-Au ternary  metallic   [39]  HE X J,  AKER W G, PELAEZ M,  et al.  Assessment of
                 nanoparticles with the enhanced peroxidase-like activity for ultrafast   nitrogen-fluorine-codoped TiO 2 under visible light for degradation of
                 colorimetric detection  of H 2O 2[J].  Sensors and Actuators B:   BPA: Implication for field remediation[J]. Journal of Photochemistry
                 Chemical, 2018, 259: 775-783.                     and Photobiology A: Chemistry, 2016, 314: 81-92.
            [21]  SUN Y, YANG Z  X,  TIAN P F,  et al.  Oxidative degradation of   [40]  HUANG  R X, FANG Z Q, YAN X M,  et al.  Heterogeneous
                 nitrobenzene by a Fenton-like reaction with  Fe-Cu  bimetallic   sono-Fenton catalytic degradation of bisphenol A by Fe 3O 4 magnetic
                 catalysts[J]. Applied Catalysis B: Environmental, 2019, 244: 1-10.     nanoparticles under neutral condition[J]. Chemical Engineering
            [22]  WU J J X, WANG X  Y, WANG  Q,  et al.  Nanomaterials with   Journal, 2012, 197: 242-249.
                 enzyme-like characteristics (nanozymes): Next-generation artificial   [41]  HUANG Z J, WU P X, GONG B N, et al. Immobilization of visible
                 enzymes (Ⅱ)[J]. Chemical Society  Reviews, 2019, 48(4): 1004-   light-sensitive (N,Cu) co-doped TiO 2 onto rectorite for photocatalytic
                 1076.                                             degradation of p-chlorophenol in aqueous solution[J]. Applied Clay
            [23]  RODNEY J D, DEEPAPRIYA S, VINOSHA P A, et al. Photo-Fenton   Science, 2017, 142: 128-135.
                 degradation  of  nano-structured La doped CuO  nanoparticles
                 synthesized by combustion technique[J]. Optik, 2018, 161: 204-216.          （下转第 1774 页）