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第 8 期孙琳，等: Mn 3 O 4 @SiO 2 核壳磁性复合材料对钼（Ⅵ）的吸附性能 ·1683·

[11] Lou X W, Archer L A, Yang Z. Hollow micro-nanostructures:
Synthesis and applications[J]. Adv Mater, 2008, 20(21): 3987-4019.
[12] Yu Changwu (于常武), Gao Chao (高超), Wang Lin (王琳).
Adsorption performance of molybdenum onto humus[J]. Environmental
Engineering (环境工程), 2015, 33(6): 10-14.
[13] Yu Changwu ( 于常武 ), Gao Chao ( 高超 ). Performance and
2
mechanism studies of adsorption molybdenum (MoO 4 ) from waste
by ulothrix[J]. Environmental Pollution and Prevention (环境污染与
防治), 2015, 37(7): 55-60.
[14] Jiang Debin (姜德彬), Yu Jing (余静), Cheng Qingfeng (程庆峰), et
al. Preparation and characterization of comositite magnetic material
Mn-Zn ferrite/SiO 2[J]. Environmental Protection of Chemical
Industry (化工环保), 2015, 35(5): 536-541.
[15] Pu Shengyan (蒲生彦), Wang Kexin (王可心), Ma Hui (马慧), et al.
Adsorption properties of magnetic chitosan hydrogelmicrospheres to
Pb(Ⅱ) from aqueous solutions[J]. China Environmental Science (中

国环境科学), 2018, 38(4): 1364-1370.
图 8 循环次数对钼（Ⅵ）吸附的影响 [16] Li Jiapeng (李家朋). Preparation and magnetic characterization of
Fig. 8 Effect of number of cycles on the adsorption of Mo nanoparticle[J]. Science & Technology Vision (科技视界), 2013,
(Ⅵ) (24): 322-323.
[17] Huang Jianhui (黄建辉), Lin Wenting (林文婷), Xie Liyan (谢丽燕).
Preparation and adsorption performance of porous spherical silica[J].
3 结论 Chinese Journal of Material Research (材料学报), 2017, 31(4): 309-313.
[18] Yang Y, Liu J, Li X, et al. Organosilane-assisted transformation from
core-shell to yolk-shell nanocomposites[J]. Chemistry of Materials,
（1）采用氧化法和正硅酸乙酯水解法制备了 2011, 23(16): 3676-3684.
[19] Zhu Y, Fang Y, Borchardt L, et al. PEGylated hollow mesoporous
Mn 3 O 4 @SiO 2 复合材料，经 SEM、TEM 和 VSM 表 silica nanoparticles as potential drug delivery vehicle[J]. Microporous
&Mesoporous Materials, 2011, 141(1/2/3): 199-206.
征表明，该复合材料为核壳磁性纳米材料，具有磁 [20] Pourhashem S, Vaezi M R, Rashidi A. Investigating the effect of
SiO 2-graphene oxide hybrid as inorganic nanofiller on corrosion
响应迅速的特点。 protection properties of epoxy coatings[J]. Surface & Coatings
（2）Mn 3 O 4 @SiO 2 磁性纳米材料可以快速吸附 Technology, 2017, 311: 282-294.
[21] Hu L X, Deng G H, Lu W C, et al. Peroxymonosulfate activation by
钼（Ⅵ），初次饱和吸附量为 145.35 mg/g，其吸附 Mn 3O 4/metal‐organic framework for degradation of refractory
aqueous organic pollutant rhodamine B[J]. Chinese Journal of
过程遵循 Langmuir 等温吸附模型，吸附动力学行 Catalysis, 2017, 38(8): 1360-1372.
为符合准二级动力学模型；Mn 3 O 4 @SiO 2 复合材料 [22] Xu J, Deng Y Q, Zhang X M, et al. Preparation, characterization, and
kinetic study of a core–shell Mn 3O 4@SiO 2 nanostructure catalyst for
使用 10 次后，饱和吸附量为初次饱和吸附量的 CO oxidation[J]. ACS Catal, 2014, 4(11): 4106-4115.
[23] Yan X Y, Zhou Z G, Wang L, et al. Folate conjugated Mn 3O 4@SiO 2
91.90%，具有良好的吸附性能。 nanoparticles for targeted magnetic resonance imaging in vivo[J].
Materials Research Bulletin, 2014, 57(10): 97-102.
（3）该磁性纳米复合材料富集回收废水中的钼 [24] Hu H, Dai A T, Sun J, et al. Aptamer-conjugated Mn 3O 4@SiO 2
core–shell nanoprobes for targeted magnetic resonance imaging[J].
（Ⅵ）以及修复水体中钼（Ⅵ）污染等具有一定的 Nanoscale, 2013, 5(21): 10447-10454.
应用前景。 [25] Lang Ting (郎婷), Xu Dongdong (许东东), Yi Mengyu (易梦雨), et
al. Preparation of nanosized Mn 3O 4 in oxidative medium of hydrogen
peroxide[J]. Applied Chemical Industry (应用化工), 2013, 43(12):
参考文献： 2135-2137.
[26] Ozkaya T, Baykal A, Kavas H, et al. A novel synthetic route to
[1] Tu Y J, Chan T S, Tu H W, et al. Rapid and efficient removal/ Mn 3O 4 nanoparticles and their magnetic evaluation[J]. Physica B:
recovery of molybdenum onto ZnFe 2O 4 nanoparticles[J]. Chemosphere, Condens Matter, 2008, 43(19/20): 3760-3764.
2016, 148(4): 452-458. [27] Ishii M, Nakahira M, Yamanaka T. Infrared absorption spectra and
[2] Ma Yingying (马英英), Zhang Lei (张磊). The influence of caution distributions in (Mn, Fe) 3O 4[J]. Solid State Commun, 1972,
molybdenum on xanthine oxidase activity in mice[J]. Feed Review 11(1): 209-212.
(饲料博览), 2016, (3): 36-39. [28] Zhao Hengqin (赵恒勤), Ning Yangkun (宁阳坤), Wang Wei (王威),
[3] Qian Dongxu (钱冬旭), Zhang Yalei (张亚雷), Zhou Xuefei (周雪 et al. Experimental study on adsorption of molybdenum by D314
飞), et al. Research progress of molybdenum polluted water treatment resin[J]. Mining and Metallurgical Engineering (矿冶工程), 2018,
technology[J]. Chemical Industry and Engineering Progress (化工进 38(1): 81-87.
展), 2016, 35(2): 617-623. [29] Liu Zhe (刘哲), Zhang Yuefei (张越非), Chi Ru’an (池汝安).
[4] Brion-Roby R, Gagnona J, Nosratic S, et al. Adsorption and Adsorption kinetics and thermodynamics of pueraia isoflavonoids on
desorption of molybdenum (Ⅵ) in contaminated water using a chitosan HPD-100 macroporous resin[J]. Journal of Wuhan Institute of
sorbent[J]. Journal of Water Process Engineering, 2018, 23(3): 13-19 Technology (武汉工程大学学报), 2015, 37(4): 17-22.
[5] World Health Organization. Molybdenum in drinking-water[M]. [30] Tessier A, Compbell P. Sequential extraction proeedure for the speciation
Geneva in Switzerland: WHO Press, 2011: 10-11. of partieulate traee metals[J]. Anal Chem, 1979, 51(7): 844-851.
[6] Tu Y J, You C F, Chang C K, et al. XANES evidence of molybdenum [31] Brion Roby R, Gagnona A J, Nostratic S, et al. Adsorption and
adsorption onto novel fabricated nano-magnetic CuFe 2O 4[J]. Chemical desorption of molybdenum (Ⅵ) in contaminated water using a
Engineering Journal, 2014, 244(10): 343-349. chitosan sorbent[J]. Journal of Water Process Engineering, 2018, 23:
[7] ChenYuan (陈远). Study on water pollution of lower reaches in zunyi 13-19.
Mo-Ni mine and its biotoxicity[J]. Technological Innovation and [32] Saptiama I, Kaneti Y V, Suzuki, et al. Template-free fabrication of
Application (科技创新与应用), 2012,(23): 121-122. mesoporous alumina nanospheres using post-synthesis water-ethanol
[8] Guo Zhijun (郭志军), Wang Yanqiu (王艳秋). Status and counter treatment of monodispersed aluminium glycerate nanospheres for
measures of Mo pollution in Wujintang reservoir[J]. Environmental molybdenum adsorption[J]. Small, 2018, 14(21): 1800474.
Science Guide (环境科学导刊), 2007, 26(4): 59-60 [33] Tu Y J, Chan T S, Tu H W, et al. Rapid and efficient removal/
[9] Zhang Jie (张捷), Wang Xiaoqin (王小琴), Cao Huabin (曹华斌), et recovery of molybdenum onto ZnFe 2O 4 nanoparticles[J]. Chemosphere,
al. Effects of Mo pollution on livestock and poultry production in 2016, 148(4): 452-458.
southern Jiangxi[J]. Jiangxi Journal of Animal Husbandry and [34] Fumihiko O,Takehiro N,Naohito K. Adsorption capability of virgin
Veterinary (江西畜牧兽医杂志), 2010, (5): 8-12. and calcined wheat bran for molybdenum present in aqueous solution
[10] Hamed M M, Rizk H E, Ahmed I M. Adsorption behavior of and elucidating the adsorption mechanism by adsorption isotherms,
zirconium and molybdenum from nitric acid medium using low-cost kinetics, and regeneration[J]. Journal of Environmental Chemical
adsorbent[J]. Journal of Molecular Liquids, 2018, 249(1): 361-370. Engineering, 2018, 6(4): 4459-4466.

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