Page 45 - 《精细化工》2022年第3期
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第 3 期                          蒋丽红,等:  凹凸棒石复合分离膜的研究进展                                    ·467·


            深入的研究,不仅要满足复合膜的稳定性要求,还应                                nanosheets in mixed  matrix membranes for CO 2 separation[J].
                                                                   Chemistry of Materials, 2020, 32(10): 4174-4184.
            该注重复合膜的使用寿命及膜生产过程的“绿色化”。                           [17]  CHA-UMPONG  W, HOSSEINI E, RAZMJOU  A,  et al. New
                (2)ATP 复合分离膜的选择性是膜分离技术的                            molecular understanding of hydrated ion trapping mechanism during
                                                                   thermally-driven desalination by pervaporation using GO membrane[J].
            关键因素之一,对于不同类型的混合物,还应该考                                 Journal of Membrane Science, 2020, 598: 117687.
            虑通过不同改性方法改变 ATP 的孔径大小,提高分                          [18]  ESMAEILI-FARAJ S H, HASSANZADEH A, SHAKERIANKHOO
                                                                   F, et al. Diesel fuel desulfurization by alumina/polymer nanocomposite
            离效率。对于疏水性/亲水性/疏油性/亲油性的基膜                               membrane: Experimental analysis and modeling  by the response
            材料,应确保膜材料表面微/纳米结构具有特殊官能                                surface methodology[J].  Chemical  Engineering and Processing:
                                                                   Process Intensification, 2021, 164: 108396.
            团和稳定的化学组成,以提高膜材料的选择性。                              [19]  ZHANG B B, YAN Q J, CHEN G, et al. Fabrication of mixed matrix
                (3)ATP 复合分离膜展现出良好的 CO 2 分离能                        membranes with zinc ion loaded titanium dioxide for improved CO 2
                                                                   separation[J]. Separation and Purification Technology, 2021, 254: 117472.
            力,可以尝试制备更多不同类型的 ATP 复合分离膜。                         [20]  ZHANG J G, XU  Z W, SHAN  M J,  et al. Synergetic effects of
            工业化带来严重的油水混合问题,也有望在 ATP 复                              oxidized carbon nanotubes and graphene oxide on fouling control
                                                                   and anti-fouling mechanism of polyvinylidene fluoride ultrafiltration
            合分离膜上实现突破。                                             membranes[J]. Journal of Membrane Science, 2013, 448: 81-92.
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