第 9 期                       张银萍，等:  铁基柱撑蒙脱石的制备及其对芘的吸附                                   ·1917·


                 Adsorption mechanism of titanium  pillared montmorillonite on   Fe-intercalated/pillared clay[J]. Journal of Colloid & Interface
                 nickel and manganese ions[J]. Fine Chemicals (精细化工), 2019,   Science, 2008, 324(1/2): 142-149.
                 36(12): 2482-2490.                            [26]  WU P X (吴平霄), ZHANG H F (张惠芬), GUO J G (郭九皋), et al.
            [19]  SHAO C J, NIE D K, ZHAI Z Q, et al. Internal surface adsorption of   Adsorption of phenol on inorganic-organic pillared montmorillonite
                 methane in the microporous and the  mesoporous montmorillonite   [J]. Geochemistry (地球化学), 1999, 28(1): 58-69.
                 models[J]. Journal of the Korean Physical Society, 2018, 72(9): 1039-1044.   [27]  SUN Z M, PARK Y, ZHENG S L, et al. Thermal stability and hot-stage
            [20] GUAN Y (关岳), SUN Q L (孙钦廉), ZHOU X Y (邬行彦), et al.   Raman spectroscopic study of Ca-montmorillonite modified with
                 Improvement of determination and calculation method  of specific   different surfactants: A comparative study[J]. Thermochimica Acta,
                 surface area and pore size distribution[J]. Acta Chimica Sinica (化学  2013, 569(10): 151-160.
                 学报), 1990, 48(5): 424-430.                    [28]  SUN H J (孙红娟), PENG T J (彭同江), LIU Y (刘颖). Method and
            [21]  LIN X P (林雄萍), YUAN J L (袁嘉隆), LIANG J (梁杰), et al. The   principle of layer charge characterization of layered silicate minerals
                 effect of setting relative pressure points on the measurement values   with expansive crystal layers[J]. Acta Minera Sinica (矿物学报), 2007,
                 of surface area and pore distribution[J]. Experimental Technology   27(1): 19-24.
                 and Management (实验技术与管理), 2014, 31(9): 55-58.   [29]  LIU X W (刘晓文), MAO X X (毛小西), LIU Z (刘庄),  et al.
            [22] GE  L  G(格雷格). Adsorption, specific surface  and porosity[M].   Preparation of Ni-Al-based pillared montmorillonite and study of its
                 Beijing: Chemical Industry Press (化学工业出版社), 1989.   channel structure[J]. Mineral Rock (矿物岩石), 2010, 30(4): 7-11.
            [23]  WANG J, HUANG C P, ALLEN H E, et al. Adsorption characteristics of   [30]  LIU S, YANG J H, CHOY J H. Microporous SiO 2-TiO 2  nanosols
                 dye onto  sludge  particulates[J]. Journal of Colloid & Interface   pillared montmorillonite for photocatalytic decomposition of methyl
                 Science, 1998, 208(2): 518-528.                   orange[J].  Journal of Photochemistry  and Photobiology  A: Chemistry,
            [24]  LIAO K J(廖克俭). Catalyst analysis[M]. Shenyang: Northeastern   2006, 179(1/2): 75-80.
                 University Press(东北大学出版社), 2000.              [31]  TONG W, ZHAO Y L, ZHANG T T, et al. Effect of anions species
            [25]  YUAN P, ANNABI-BERGAYA F, TAO Q, et al. A combined study   on copper removal from wastewater by using mechanically activated
                 by XRD, FTIR,  TG and HRTEM on the structure of delaminated   calcium carbonate[J]. Chemosphere, 2019, 230(9): 127-135.


            （上接第 1863 页）                                           [J]. Crystal Growth & Design, 2017, 17(1): 308-316.
                                                               [21]  DE ALMEIDA A C, TORQUETTI C, FERREIRA P O,  et al.
            [15]  HE S F, ZHANG  X R,  ZHANG S,  et al. An investigation into   Cocrystals of ciprofloxacin with nicotinic and isonicotinic acids:
                 vortioxetine salts: Crystal structure, thermal stability, and solubilization   Mechanochemical synthesis, characterization, thermal and solubility
                 [J]. Journal of Pharmaceutical Sciences, 2016, 105(7): 2123-2128.     study[J]. Thermochimica Acta, 2020, 685:178346.
            [16]  ZHANG S, ZHANG X R, HE S F, et al. Syntheses, crystal structures
                 and theoretical studies of three novel salts  of  vortioxetine and the   [22]  LÖBMANN K, STRACHAN C, GROHGANZ H, et al. Co-amorphous
                 investigation of their solubility[J]. Chinese Journal  of  Structural   simvastatin and glipizide combinations show improved physical stability
                 Chemistry, 2016, 35(11): 1645-1654.               without evidence of intermolecular interactions[J]. European Journal
            [17]  ZHANG X R, GAO L, HE G Y, et al. Investigations on the solubility   of Pharmaceutics and Biopharmaceutics, 2012, 81(1): 159-169.
                 of vortioxetine based on X-ray structural data and crystal contacts[J].   [23]  LÖBMANN K, LAITINEN R, CROHGANZ H, et al. A theoretical
                 Crystals, 2019, 9(10): 536.                       and spectroscopic study of co-amorphous naproxen and indomethacin
            [18]  GAO L,  ZHANG  X R,  YANG S P,  et al. Improved  solubility of   [J]. International Journal of Pharmaceutics, 2013, 453(1): 80-87.
                 vortioxetine using C2-C4 straight-chain dicarboxylic acid salt hydrates   [24]  HADZIJA O, SPOLJAR B. Quantitative determination of carboxylate
                 [J]. Crystals, 2018, 8(9): 352.                   by infrared spectroscopy: Application to humic acids[J]. Fresenius
            [19]  BOLLA G, NANGIA A. Clofazimine mesylate: A high solubility stable   Journal of Analytical Chemistry, 1995, 351(7): 692-693.
                 salt[J]. Crystal Growth & Design, 2012, 12(12): 6250-6259.   [25]  ANDRE´ V, FERNANDES A, SANTOS P P, et al. On the track of new
            [20]  GOPI S  P, BANIK M, DESIRAJU G R. New cocrystals of   multicomponent gabapentin crystal forms: Synthon competition and
                 hydrochlorothiazide: Optimizing solubility and  membrane  diffusivity   pH stability[J]. Crystal Growth & Design, 2011, 11(6): 2325-2334.


            （上接第 1903 页）                                       [23]  MOUSSET E, KO Z T, SYAFIQ M, et al. Electrocatalytic activity
                                                                   enhancement of a graphene ink-coated carbon cloth cathode for
            [19]  ZHU J Y, XIAO X, ZHENG K, et al. KOH-treated reduced graphene
                                                                   oxidative treatment[J]. Electrochimica Acta, 2016, 222: 1628-1641.
                 oxide: 100% selectivity for H 2O 2 electroproduction[J]. Carbon, 2019,   [24]  ZHOU W,  MENG X X,  GAO J H,  et al. Hydrogen peroxide
                 153: 6-11.                                        generation from O 2 electroreduction for environmental remediation:
            [20]  FAVARO M, PERINI L, AGNOLI S, et al. Electrochemical behavior   A state-of-the-art review[J]. Chemosphere, 2019, 225: 588-607.
                 of N and Ar implanted highly oriented pyrolytic graphite substrates   [25]  KHOMENKO V G, BARSUKOV V Z, KATASHINSKII A S. The
                 and activity toward oxygen reduction reaction[J]. Electrochimica   catalytic activity of conducting polymers toward oxygen reduction[J].
                 Acta, 2013, 88: 477-487.                          Electrochimica Acta, 2005, 50(7/8): 1675-1683.
            [21]  SHENG Z H, SHAO L, CHEN J J, et al. Catalyst-free synthesis of   [26] HUANG G (黄桂). Advanced treatment of dye wastewater through
                 nitrogen-doped graphene via thermal annealing graphite oxide with   bio-electro-Fenton coupled with polypyrrole  modified cathode[D].
                 melamine and its excellent electrocatalysis[J]. ACS Nano, 2011, 5(6):   Wuxi: Jiangnan University (江南大学), 2019.
                 4350-4358.                                    [27]  HUANG H L, HAN C L, WANG G W, et al. Lignin combined with
            [22]  LYU Z S, CHEN Y F, WEI H C, et al. One-step electrosynthesis of   polypyrrole as a renewable cathode material for H 2O 2 generation and
                 polypyrrole/graphene oxide composites for microbial  fuel cell   its application in the electro-Fenton process for azo dye removal[J].
                 application[J]. Electrochimica Acta, 2013, 111: 366-373.     Electrochimica Acta, 2018, 259: 637-646.