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Communications, 2007, 27(24): 2820-2822. catalysis? [J]. Industrial Engineering Chemistry Research, 2016,
[8] Yoon J W, Seo Y K, Hwang Y K, et al. Controlled reducibility of a 55(48): 12326-12333.
metal-organic framework with coordinatively unsaturated sites for [14] Bezrodna T, Puchkovska G, Shimanovska V, et al. Pyridine-TiO 2,
preferential gas sorption[J]. Angewandte Chemie Internattional Surface interaction as a probe for surface active centers analysis[J].
Edition, 2010, 49(34): 5949-5952. Applied Surface Science, 2003, 214(1/2/3/4): 222-231.
[9] Seo Y K, Ji W Y, Ji S L, et al. Large scale fluorine-free synthesis of [15] Alan J D, Thomasf S, Norman H. Hydroformylation process:
hierarchically porous iron(Ⅲ) trimesate MIL-100(Fe) with a zeolite EP0016286[P]. 1980-10-1.
MTN topology[J]. Microporous and Mesoporous Materials, 2012, [16] Shen W, Tompsett G A, Xing R, et al. Vapor phase butanal
157(27): 137-145. self-condensation over unsupported and supported alkaline earth
[10] Márquez A G, Demessence A, Platero-Prats A E, et al. Green metal oxides[J]. Journal of Catalysis, 2012, 286(2): 248-259.
microwave synthesis of MIL-100(Al, Cr, Fe) nanoparticles for [17] Idriss H, Kim K S, Barteau M A. Carbon arbon bond formation via
thin-film elaboration[J]. European Journal of Inorganic Chemistry. aldolization of acetaldehyde on single crystal and polycrystalline
2012，2012(32): 5165-5174. TiO 2, surfaces[J]. Journal of Catalysis, 1993, 24(15): 119-133.
[11] Shi J, Hei S T, Liu H H, et al. Synthesis of MIL-100(Fe) at low [18] Chen Cuina(陈翠娜), Liu Xiaohong(刘肖红), An Hualiang(安华良),
temperature and atmospheric pressure[J]. Journal of Chemistry, et al. n-Butyraldehyde aldol self-condensation catalyzed by
2013.DOI: 10.1155/2013/792827. H 4SiW 12O 40/SiO 2[J]. CIESC Journal (化工学报), 2014, 65(6): 2106-
[12] Shi Jing (石静). Preparation of MIL-l00(Fe) and HPW@MIL- 2112.
100(Fe) catalysts and their catalytic properties[D]. Jinhua: Zhejiang [19] Kong Y H, Cheng X M, An H L, et al. Preparation and
Normal University(浙江师范大学) , 2014. characterization of H 4SiW 12O 40@MIL-100(Fe) and its catalytic
[13] Zhao L L, An H L, Zhao X Q, et al. TiO 2-catalyzed n-valeraldehyde performance for synthesis of 4, 4′-MDA [J]. Chinese Journal of
self-condensation to 2-propyl-2-heptenal：acid catalysis or base Chemical Engineering, 2018, 26(2): 330-336.

（上接第 93 页） Polymer Materials Science & Engineering (高分子材料科学与工
程), 2011, 27(10): 8-10.
[10] Costa V, Nohales A, Félix P, et al. Structure-property relationships of [18] Desantis D, Mason J A, James B D, et al. Techno-economic analysis
polycarbonate diol-based polyurethanes as a function of soft segment of metal-organic frameworks for hydrogen and natural gas storage[J].
content and molar mass[J]. Journal of Applied Polymer Science, Energy & Fuels, 2017, 31(2): 2024-2032.
2015, 132(12): 41704-41710. [19] Li Y L, Zhao Y, Wang P, et al. Multifunctional metal-organic
[11] Brignou P, Gil M P, Casagrande O, et al. Polycarbonates derived frameworks with fluorescent sensing and selective adsorption
from green acids, ring-opening polymerization of seven-membered properties[J]. Inorganic Chemistry, 2016, 55(22): 11821-11830.
cyclic carbonates[J]. Macromolecules, 2011, 43(19): 8007-8017. [20] Vu T V, Kosslick H, Schulz A, et al. Hydroformylation of olefins over
[12] Qin Yusheng (秦玉升), Gu Lin (顾林), Wang Xianhong (王献红). rhodium supported metal-organic framework catalysts of different stru-
Progress in functional carbon dioxide based aliphatic polycarbonates[J]. cture[J]. Microporous Mesoporous Materials, 2013, 177(8): 135-142.
Acta Polymerica Sinica (高分子学报), 2013,(5): 600-608. [21] Kuntal M, Pengfei J, Francis X G,et al. Metal-organic framework
[13] Mazurek M, Bruliński T, Tomczyk K, et al. Aliphatic-aromatic nodes support single-site magnesium-alkyl catalysts for hydroboration
poly(ester-carbonate)s obtained from simple carbonate esters, and hydroamination reactions[J]. Journal of the American Chemical
α,ω-aliphatic diols and dimethyl terephthalate[J]. Journal of Polymer Society, 2016, 138(24): 7488-7491.
Research, 2015, 22(3): 1-16. [22] Naeimi S, Faghihian H. Performance of novel adsorbent prepared by
[14] Hao Junsong (郝俊松), Du Juan (杜娟), Liu Shaoyong (刘少勇), et magnetic metal-organic framework (MOF) modified by potassium
al. The preparation technology of polycarbonate diols catalyzed by nickel hexacyanoferrate for removal of Cs+ from aqueous solution[J].
amines[J]. Polymer Materials Science & Engineering (高分子材料科 Separation & Purification Technology, 2017, 175(24): 255-265.
学与工程), 2010, 26(5): 9-12. [23] Song Huihua (宋会花), Yang Fang (杨芳), Wang Jiye (王继业), et
[15] Li Jinli (李金丽), Zhou Hongyong (周宏勇), Li Yunqing (李云庆), et al. Synthesis and fluorescence properties of the Tb(Ln) complexes
al. Synthesis of polycarbonate diol through the reaction of ethylene with trimesic Acid (Ln=Y, Gd) [J]. Spectroscopy & Spectral Ana
carbonate with diol[J]. Polymer Materials Science & Engineering (高 lysis (光谱学与光谱分析), 2007, 27(10): 2093-2097.
分子材料科学与工程), 2012, 28(5): 129-132. [24] Wu M, Guo J, Jing H. Organic base catalyzed oligomerization of
[16] Hao Junsong (郝俊松), Du Juan (杜娟), Zuo Lin (左琳), et al. propylene carbonate and bisphenol A, unexpected polyether diol
Preparation of poly(1, 6-hexanediol) carbonate diols catalyzed by formation[J]. Catalysis Communications, 2008, 9(1): 120-125.
Ti(OBu) 4[J]. Polymer Materials Science & Engineering (高分子材料 [25] Zhang Yi (张毅), Yang Xiangui (杨先贵), Wang Qingyin (王庆印),
科学与工程), 2010, 26(12): 12-15. et al. Synthesis of nitro-modified MOF-5 and its application on
[17] Wang Liping (王丽苹), Xiao Bin (萧斌), Wang Gongying (王公应). ctalyzing the thermal decomposition of carbamates[J]. Chemical
Transesterification between diphenyl carbonate and 1, 4-butanediol Journal of Chinese Uiversities-Chinese (高等学校化学学报), 2014,
to polycarbonate diols catalyzed by titanium oxide acetylacetonate[J]. 35(3): 613-618.

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