Page 27 - 《精细化工》2021年第5期
P. 27

第 5 期                           高党鸽,等:超疏水抗菌表面的研究进展                                       ·881·


                 hydrophobic cotton fabrics treated with cyclic polysiloxane quaternary   Materials Review (材料导报), 2019, 33(3): 550-557.
                 ammonium salt[J]. Fibers and Polymers, 2019, 20(7): 1368-1374.   [47]  MAO X Y (毛晓妍), WANG Y X (王玉新), WANG H Y (汪翰阳),
            [30]  SONG W, GAWARE V S, MAR M,  et al. Functionalized   et al. Research progress on the preparation and performance of zeolite
                 superhydrophobic biomimetic chitosan-based films[J]. Carbohydrate   imidazole ester frameworks (ZIFs)[J]. Contemporary Chemical
                 Polymers, 2010, 81(1): 140-144.                   Industry (当代化工), 2018, 47(8): 1698-1701.
            [31]  LYU D D, FANG N, ZHANG W G. A PDMS modified polyurethane/   [48]  SURYAPRABHA  T, SETHURAMAN M G. Fabrication of copper
                 Ag composite coating with super-hydrophobicity and low infrared   based superhydrophobic self-cleaning antibacterial  coating  over
                 emissivity[J]. Infrared Physics & Technology, 2020, 108: 103351.   cotton fabric[J]. Cellulose, 2017, 24(1): 395-407.
            [32]  MA W J, DING Y C, ZHANG M J, et al. Nature-inspired chemistry   [49]  TRIPATHY A, KUMAR A, SREEDHARAN S, et al. Fabrication of
                 toward hierarchical superhydrophobic, antibacterial and biocompatible   low-cost flexible  superhydrophobic antibacterial surface with  dual-
                 nanofibrous membranes for effective UV-shielding, self-cleaning and   scale roughness[J]. ACS Biomaterials Science & Engineering, 2018,
                 oil-water separation[J]. Journal of Hazardous Materials, 2019, 384:   4(6): 2213-2223.
                 121476.                                       [50]  CHEN H, JIN Y Y, LEI L. Construction of robust superhydrophobic
            [33]  MARIA S M, RAFEAL G, JORGE P, et al. Functionalization of silica   film combing povidone iodine for  high efficient self-cleaning and
                 with amine and ammonium alkyl chains, dendrons and dendrimers:   durable bactericidal  properties[J].  Applied Surface Science, 2018,
                 Synthesis and antibacterial properties[J]. Materials Science  and   462: 149-154.
                 Engineering C, 2019, 109: 110526.             [51]  WU M C, MA B H, PAN T Z, et al. Silver-nanoparticle-colored cotton
            [34]  CHENG Q L, GUO X W, ZOU J W, et al. A photo-crosslinked hybrid   fabrics with tunable colors and durable antibacterial and self-healing
                 interpenetrating polymer network (IPN) for antibacterial coatings on   superhydrophobic properties[J]. Advanced Functional Materials,
                 denture base materials[J]. New Journal of Chemistry, 2019, 43(42):   2016, 26(4): 569-576.
                 6647-16655.                                   [52]  XU X  L (徐小龙), HAO Z D (郝振东), LI H Q (李浩强),  et al.
            [35]  XIAO L  H (肖凌寒), LI N (李娜), BU D  L (卜聃琳). Preparation   Modification of LiFePO 4 based on zeolite imidazole ester skeleton-8[J].
                 and antibacterial properties  of Fe 3O 4@SiO 2 nanoparticles modified   Chinese Journal of  Applied Chemistry (应用化学), 2018, 35(8):
                 by quaternary ammonium halide polymer[J]. Journal of Changchun   939-945.
                 University of Technology (长春工业大学学报), 2019, 40(4): 313-   [53]  MIAO W Z. Self-cleaning and antibacterial zeolitic imidazolate
                 318.                                              framework  coatings[J].  Advanced Materials Interfaces, 2018, 5(14):
            [36]  RAUNER N, MUELLER C, RING S, et al. A coating that combines   1800167.
                 lotus-effect and contact-active antimicrobial properties on silicone[J].   [54]  YUE  X J, LI Z  D,  ZHANG T,  et al. Design  and fabrication of
                 Advanced Functional Materials, 2018, 28(29): 1801248.     superwetting fiber-based membranes for  oil/water  separation
            [37]  ZARZUELA R, CARBU M, GIL M L, et al. Ormosils loaded with   applications[J]. Chemical Engineering Journal, 2019, 364: 292-309.
                 SiO 2  NPs  functionalized with Ag as multifunctional superhydrophobic/   [55]  WANG X Y, LI M J, SHEN Y Q, et al. Facile preparation of loess
                 biocidal/consolidant treatments for buildings conservation[J].   coated membrane for multifunctional surfactant-stabilized oil-in-water
                 Nanotechnology, 2019, 30: 45701.                  emulsions separation[J]. Green Chemistry, 2019, 21(11): 3190-3199.
            [38]  SELIM M S, YANG H, WANG F Q, et al. Silicone/Ag@SiO 2 core-   [56]  HONG H R, KIM J, PARK C H. Facile fabrication of multifunctional
                 shell nanocomposite as a self-cleaning antifouling coating material[J].   fabrics: Use of copper and silver nanoparticles for antibacterial,
                 RSC Advances, 2018, 8(18): 9910-9921.             superhydrophobic, conductive fabrics[J]. RSC Advances, 2018, 8(73):
            [39]  YANG H, YOU W H, SHEN Q H, et al. Preparation of lotus-leaf-like   41782-41794.
                 antibacterial film based on mesoporous silica microcapsulesupported   [57]  LYU Y F, LI Q R, HOU Y T, et al. Facile preparation of asymmetric
                 Ag nanoparticles[J]. RSC Advances, 2014, 4: 2793-2796.   wettability Janus  cellulose membrane for switchable emulsions
            [40]  GHASEMI N, SEYFI J, ASADOLLAHZADEH  M J.  Imparting   separation and antibacterial property[J]. ACS Sustainable Chemistry
                 superhydrophobic and antibacterial properties onto the cotton fabrics:   & Engineering, 2019, 7(17): 15002-15011.
                 Synergistic effect of zinc oxide nanoparticles and octadecanethiol[J].   [58]  XUE B L, GAO L C, HOU Y P, et al. Temperature controlled water/
                 Cellulose, 2018, 25(7): 4211-4222.                oil wettability of a surface fabricated by a block copolymer: Application
            [41]  GUN W J. Superhydrophobic and antibacterial properties of cotton   as a dual water/oil on-off switch[J]. Advanced Materials, 2013,
                 fabrics treated with PVDF and nano-ZnO through phase inversion   25(2): 273-277.
                 process[J]. Fibers and Polymers, 2018, 9: 1835-1842.   [59]  FU Y, JIN B Y, ZHANG Q H,  et al. pH-induced  switchable
            [42]  AGRAWAL N, JASMINE S, PEARLIE S, et al. Green synthesis of   superwettability of efficient antibacterial fabrics for durable selective
                 robust superhydrophobic antibacterial and UV-blocking cotton   oil/water separation[J]. ACS Applied Materials & Interfaces, 2017,
                 fabrics by a dual-stage silanization approach[J]. Advanced Materials   9(35): 30161-30170.
                 Interfaces, 2019, 6(11): 1900032.             [60]  ZHAI M J, GONG Y F, CHEN  X  Y,  et al. Mass-producible
            [43]  SHEN W L, ZHANG L S, LI X C, et al. Binary silanization and silver   hydrophobic perfluoroalkoxy/nano-silver coatings by suspension
                 nanoparticle encapsulation to create superhydrophobic cotton fabrics   flame spraying for antifouling and drag reduction applications[J].
                 with antimicrobial capability[J]. Scientific Reports, 2019, 9: 41598-   Surface and Coatings Technology, 2017, 328: 115-120.
                 45622.                                        [61]  CHENG Q L, CAO D F, LIU X J, et al. Superhydrophobic coatings
            [44]  FENG Y C (冯宇超). Preparation and performance of superhydrophobic   with self-cleaning  and antibacterial adhesion properties for denture
                 silver and  hydrophobic coatings[D]. Tianjin: Tianjin University of   base[J]. Journal of the Mechanical Behavior of Biomedical Materials,
                 Technology (天津理工大学), 2017.                        2019, 98: 148-156.
            [45]  RATHER R A, SARWARA R K, DAS N, et al. Impact of reducing   [62]  LIU G Y, XIANG J, XIA Q F, et al. Superhydrophobic cotton gauze
                 and capping agents on carbohydrates for the growth of Ag and Cu   with durably antibacterial activity  as skin wound dressing[J].
                 nanostructures and their antibacterial activities[J]. Particuology,   Cellulose, 2018, 26(2): 1383-1397.
                 2019, 43(2): 219-226.                         [63]  LU Z, LIU J, DONG C H, et al. Durable multifunctional antibacterial
            [46]  GAO D G  (高党鸽),  WANG P P (王平平), LYU  B (吕斌),  et al.   and hydrophobic cotton fabrics modified with  linear fluorinated
                 Research progress in the preparation of POSS/polymer nanocomposites[J].   pyridinium polysiloxane[J]. Cellulose, 2019, 26(12): 7483-7494.
   22   23   24   25   26   27   28   29   30   31   32