第 11 期                魏   柏，等:  氮化硼基材料制备及其对水体污染物去除的研究进展                                 ·2207·


            [8]   LIN Z D (林正得),  YAN Q W (颜庆伟), DAI W  (代文),  et al.   Engineering Aspects, 2011, 388(1/2/3): 49-58.
                 Research progress on hexagonal boron nitride-based thermalconductive   [30]  WANG R X, ZHANG D J, LIU C B. DFT study of the adsorption of
                 composites[J]. Journal of Integration Technology (集成技术), 2019,   2,3,7,8-tetrachlorodibenzo-p-dioxin on pristine and Ni-doped boron
                 8(1): 24-37.                                      nitride nanotubes[J]. Chemosphere, 2017, 168: 18-24.
            [9]   HE D Q (何冬青), LIANG J M (梁嘉鸣), LIANG B (梁兵). Advances   [31]  SONG Q  Q, FANG  Y, WANG J J,  et al. Enhanced adsorption  of
                 in synthesis of hexagonal boron nitride particles[J]. Materials Review   fluoride on  Al-modified boron  nitride nanosheets from aqueous
                 (材料导报), 2015, 29(9): 92-96.                       solution[J]. Journal of Alloysand Compounds, 2019, 793: 512-518.
            [10]  XUE  L L, LU B Z, WU  Z S,  et al. Synthesis of mesoporous   [32]  MILLAR G J, COUPERTHWAITE S J, DAWES L A, et al. Activated
                 hexagonal boron nitride fibers with high surface area for efficient   alumina for the removal of fluoride ions from high alkalinity
                 removal of organic pollutants[J]. Chemical  Engineering Journal,   groundwater: New insights from equilibrium and column studies with
                 2014, 243: 494- 499.                              multicomponent solutions[J]. Separationand Purification Technology,
            [11]  MARCHESINI S, MCGILVERY C M, BAILEY J, et al. Template-   2017, 187: 14-24.
                 free synthesis of highly porous boron nitride: Insights into pore network   [33]  KANG D J, YU X L, GE M F, et al. Insights into adsorption mechanism
                 design and impact on gas sorption[J]. ACS Nano, 2017, 11(10):   for fluoride on cactus-like amorphous alumina oxide microspheres
                 10003-10011.                                      [J]. Chemical Engineering Journal, 2018, 345: 252-259.
            [12]  LIU Z W, ZHAO  K, LUO J,  et al.  Highly efficient synthesis of   [34]  JIN H Y, JI Z J, YUAN J, et al. Research on removal of fluoride in
                 hexagonal boron nitride short fibers  with adsorption selectivity[J].   aqueous solution by alumina-modified expanded graphite composite
                 Ceramics International, 2019, 45(17): 22394-22401.   [J]. Journal of Alloysand Compounds, 2015, 620: 361-367.
            [13]  WANG M, BAI Y Q,  ZHANG  B,  et al. Large scale fabrication of   [35]  AZAMAT J, KHATAEE A, JOO S  W. Separation of copper and
                 porous boron nitride  microrods with tunable pore size for superior   mercury as heavy metals from aqueous solution using functionalized
                 copper (Ⅱ) ion adsorption[J]. Ceramics International, 2019, 45(6):   boron nitride nanosheets: A theoretical study[J]. Journal of Molecular
                 6684-6692.                                        Structure, 2016, 1108: 144-149.
            [14]  LIU F, LI S, YU D F, et al. Template-free synthesis of oxygen-doped   [36]  LI J, XIAO X, XU X W, et al. Activated boron nitride as an effective
                 bundlelike porous boron nitride for highly efficient removal of heavy   adsorbent for metal ions and organic pollutants[J]. Scientific Reports,
                 metals from wastewater[J]. ACS Sustainable Chemistry & Engineering,   2013, 3: 3208-3215.
                 2018, 6(12): 16011-16020.                     [37]  KARTHIKEYAN P, ELANCHEZHIYAN S S D, PREETHI J, et al.
            [15]  ZHANG N, LIU H, KAN H M, et al. The preparation of high-adsorption,   Mechanistic performance of polyaniline-substituted hexagonal boron
                 spherical, hexagonal boron nitride by template method[J]. Journal of   nitride composite as a highly efficient adsorbent for the removal of
                 Alloys and Compounds, 2014, 613: 74-79.           phosphate, nitrate, and hexavalent chromium ions from an aqueous
            [16]  STEHLE Y J, MEYER Ⅲ  H M , UNOCIC R R, et al. Synthesis of   environment[J]. Applied Surface Science, 2020, 511: 145543.
                 hexagonal boron nitride mono layer: Control of nucleation and   [38]  GUO Y, WANG  R X,  YAN C C,  et al. Developing boron nitride-
                 crystal morphology[J]. Chemistry of Materials, 2015, 27(23):   pyromelliticdianhydride composite for removal of aromatic pollutants
                 8041-8047.                                        from wastewater via adsorption and photodegradation[J]. Chemosphere,
            [17]  KHAN M H, LIU H K, SUN X D, et al. Few-atomic-layered hexagonal   2019, 229: 112-124.
                 boron  nitride: CVD growth, characterization, and applications[J].   [39]  O'CONNOR D, PENG T Y, LI G H, et al. Sulfur-modified rice husk
                 Materials Today, 2017, 20(10): 611-628.           biochar: A green method for the remediation of mercury contaminated
            [18]  PETROVIC M,  HAGEMANN U, HORN-VON  H M,  et al.   soil[J]. Science of the Total Environment, 2018, 621: 819-826.
                 Microanalysis of single-layer hexagonal boron nitride islands on   [40]  SHARMA D  K, LI F T, WU Y N. Electrospinning of Nafion and
                 Ir(111)[J]. Applied Surface Science, 2017, 420: 504-510.   polyvinyl alcohol into  nanofiber membranes: A facile approach to
            [19]  YU J,  QIN L, HAO  Y F,  et al. Vertically aligned boron nitride   fabricate functional adsorbent for heavy  metals[J]. Colloids and
                 nanosheets: Chemical vapor synthesis, ultraviolet light emission, and   Surfaces A-Physicochemicaland Engineering Aspects, 2014, 457(1):
                 superhydrophobicity[J]. ACS Nano, 2010, 4(1): 414-422.   236-243.
            [20]  SHI Z Y, LI Q T, JIANG R, et al. Influence of oxygen on the synthesis   [41]  VAKILI M, DENG S B, CAGNETTA G,  et al. Regeneration  of
                 of large area hexagonal boron nitride on Fe 2B substrate[J]. Materials   chitosan-based adsorbents used in heavy metal adsorption: A review
                 Letters, 2019, 247: 52-55.                        [J]. Separationand Purification Technology, 2019, 224: 373-387.
            [21] GE  L  (葛雷), QIU T (丘泰), YANG  J (杨建). Study on influence   [42]  LI S, LIU F, SU Y P, et al. Luffa sponge-derived hierarchical meso/
                 factors of h-BN nanocrystals prepared by solvothermal method[J]. Journal   macroporous boron nitride fibers as superior sorbents for heavy metal
                 of Synthetic Crystals (人工晶体学报), 2009, 38(6): 1388-1393.   sequestration[J]. Journal of Hazardous Materials, 2019, 378: 120669.
            [22]  ZHI C Y, BANDO Y, TAN C C, et al. Effective precursor for high   [43]  ROUSSEAS M, GOLDSTEIN A P, MICKELSON W, et al. Synthesis
                 yield synthesis of pure BN nanotubes[J]. Solid State Communications,   of highly crystalline  sp(2)-bonded boron nitride aerogels[J]. ACS
                 2005, 135(1/2): 67-70.                            Nano, 2013, 7(10): 8540-8546.
            [23]  LI D, ZHANG C R, LI B, et al. Low-cost preparation of boron nitride   [44]  ZHANG R Y, WAN W C, QIU L J, et al. Preparation of hydrophobic
                 ceramic powders[J]. Journal of  Wuhan University of  Technology   polyvinyl alcohol aerogel via the surface modification of boron nitride
                 (Materials Science Edition), 2012, 27(3): 534-537.   for environmental  remediation[J]. Applied Surface Science, 2017,
            [24]  CHUNG S L, HSU Y H. Combustion synthesis of boron nitride via   419: 342-347.
                 magnesium reduction under low nitrogen pressures[J]. Journal of the   [45]  OH W D, LEE M G H, UDAYANGA W D C, et al. Insights into the
                 American Ceramic Society, 2014, 97(11): 3418-3424.   single and binary adsorption of copper(Ⅱ) and nickel(Ⅱ) on hexagonal
            [25]  IKUNO T, SAINSBURY T, OKAWA D, et al. Amine-functionalized   boron nitride: Performance and  mechanistic studies[J]. Journal of
                 boron nitride nanotubes[J]. Solid State Communications, 2007, 142(11):   Environmental Chemical Engineering, 2019, 7(1): 102872.
                 643-646.                                      [46] LIU T (刘涛). Study on preparation of 2D boron nitride nanomaterials
            [26]  SAINSBURY T,  SATTI A, MAY P,  et al. Oxygen  radical   for the application of heavy metal ions removal mechanism in water
                 functionalization of boron nitride nanosheets[J]. Journal of the   [D]. Hefei: University of Science and Technology of China (中国科
                 American Chemical Society, 2012, 134(45): 18758-18771.   学技术大学), 2019.
            [27]  LEE D, LEE B, PARK K H, et al. Scalable exfoliation process for   [47]  SONG Q Q, LIANG J L, FANG Y, et al. Selective adsorption behavior/
                 highly soluble boron nitride nanoplatelets by hydroxide-assisted ball   mechanism of antibiotic contaminants on novel boron nitride bundles
                 milling[J]. Nano Letters, 2015, 15(2): 1238-1244.   [J]. Journal of Hazardous Materials, 2019, 364: 654-662.
            [28]  PAKDEL A, BANDO Y,  GOLBERG D. Plasma-assisted interface   [48]  PENDSE  A, CETINDAG S, LIN M,  et al. Charged layered boron
                 engineering of boron nitride nanostructure films[J]. ACS Nano, 2014,   nitride-nanoflake membranes for efficient ion separation and water
                 8(10): 10631-10639.                               purification[J]. Small, 2019, 15(49): e1904590.
            [29]  JONI I M,  BALGIS R,  OGI  T,  et al.  Surface functionalization for   [49]  LI J (李杰). Synthesis, characterization and activation of porous boron
                 dispersing and stabilizing hexagonal boron nitride nanoparticle by   nitride and their applications in environment and energy fields[D].
                 bead milling[J].  Colloids and Surfaces A:  Physicochemical and   Tianjin: Hebei University of Technology (河北工业大学), 2016.