Page 240 - 《精细化工》2023年第9期

P. 240

·2088· 精细化工 FINE CHEMICALS 第 40 卷

参考文献： Nanjing: Nanjing University (南京大学), 2015.
[15] KUMAR R D, THANGAPPAN R, JAVAVEL R. Synthesis and
[1] ZHAO L L, AN H L, ZHAO X Q, et al. TiO 2-catalyzed
characterization of LaFeO 3/TiO 2 nanocomposites for visible light
n-valeraldehyde self-condensation to 2-propyl-2-heptenal: Acid
photocatalytic activity[J]. Journal of Physics and Chemistry of
catalysis or base catalysis?[J]. Industrial & Engineering Chemistry
Solids, 2017, 101: 25-33.
Research, 2016, 55(48): 12326-12333.
[16] ZHANG T(张媞). Synthesis and properties of cobalt-lanthanum
[2] LIU X H (刘肖红), WU L L (吴丽丽), AN H L (安华良), et al. Aldol
based perovskite materials[D]. Zhengzhou: North China University
self-condensation of n-butyraldehyde to 2-ethyl-2-hexenal catalyzed
of Water Resources and Electric Power (华北水利水电大学), 2018.
by KF-γ-Al 2O 3[J]. Acta Petrolei Sinica(Petroleum Processing
[17] TAMAYO R, ESPINOZA-GONZÁLEZ R, GRACIA F, et al. As(Ⅲ)
Section) (石油学报: 石油加工), 2015, 31(6): 1332-1337.
removal from aqueous solution by calcium titanate nanoparticles
[3] SHYLESH S, HANNA D, GOMES J, et al. Tailoring the cooperative prepared by the sol gel method[J]. Nanomaterials, 2019, 9(5): 733-739.

acid-base effects in silica-supported amine catalysts: Applications in
[18] HUANG W Q (黄万群). Synthesis of CaTiO 3: Zn microwave dielectric
the continuous gas-phase self-condensation of n-butanal[J].
nano-ceramics by sol-gel method[D]. Hangzhou: Zhejiang University
ChemCatChem, 2014, 6(5): 1283-1290.
(浙江大学), 2012.
[4] AN H L, KONG Y H, YANG Q S, et al. Synergistic catalysis of
[19] MIAO Y M (缪亚美). Low-temperature synthesis of magnesium
acid-base bifunctional ionic liquids for pentanal self-condensation
titanate nanopowders by sol-gel method[D]. Hangzhou: Zhejiang
reaction[J]. Journal of Chemical Technology & Biotechnology, 2020, University(浙江大学), 2006.
95(3): 710-718.
[20] HAO C W (郝成伟), WU B L (吴伯麟), LI J Y (李继彦). Influence
[5] JOSE T, SUDHESSH N, SHUKLA R S. Amino functionalized
of polyethylene glycol dispersants on preparing high purity utrafine
chitosan as a catalyst for selective solvent-free self-condensation of α-Al 2O 3[J]. Materials Review (材料导报), 2007, (21): 163-167.
linear aldehydes[J]. Journal of Molecular Catalysis A: Chemical,
[21] YANG H (杨合), HAN C (韩冲), LI Q W (李清伟), et al. Effect of
2010, 333: 158-166. baking temperature on photocatalytic properties of titanium calcium[J].
[6] ZHAO L L, AN H L, ZHAO X Q, et al. TiO 2-catalyzed Journal of Functional Materials (功能材料), 2010, 41(11): 1888-
n-valeraldehyde self-condensation reaction mechanism and kinetics[J]. 1891, 1895.
ACS Catalysis, 2017, 7: 4451-4461. [22] GAO L D (高立东). Synthesis and characterization of hollow titania
[7] WANG R (王瑞). Preparation of ZrO 2 and its catalytic performance and calcium titanate & investigation on their properties[D]. Beijing:
for n-valeraldehyde self-condensation reaction[D]. Tianjin: Hebei University of Chemical Technology (北京化工大学), 2006.
University of Technology (河北工业大学), 2021. [23] DONG W X (董伟霞). Study on hydrothermal preparation, microstructure
[8] TORRES-MARTÍNEZ L M, ELENA MEZA-DE LA ROSA M, and properties of calcium titanium oxide nano/microstructures[D].
GARZA-TOVAR L L, et al. Structure sensitivity of sol-gel alkali Hangzhou: Zhejiang University (浙江大学), 2013.
tantalates, ATaO 3 (A = Li, Na and K): Acetone gas phase condensation[J]. [24] WANG D (王娣), LI B W (李步卫), AN H L (安华良), et al.
Advanced Materials Research, 2010, 132: 61-67. MIL-100(Fe) catalyzed self-condensation of n-valeraldehyde[J]. Fine
[9] KLEINEBERG H, EISENACHER M, LANGE H, et al. Perovskites Chemicals (精细化工), 2019, 36(1): 94-100.
and metal nitrides as catalysts in the base-catalysed aldol addition of [25] IDRISS H, KIM K S, BARTEAU M A. Carbon carbon bond

isobutyraldehyde to formaldehyde[J]. Catalysis Science & Technology, formation via aldolization of acetaldehyde on single crystal and
2016, 6(15): 6057-6065. polycrystalline TiO 2 surfaces[J]. Journal of Catalysis, 1993, 139(1):
[10] ZHAO H Y (赵鸿宇). Synthesis and characterization of CaTiO 3 119-133.
particles with controlled shape and size[D]. Lanzhou: Lanzhou [26] ORDOMSKY V V, SUSHKEVICH V L, IVANOVA I I. Study of
University (兰州大学), 2013. acetaldehyde condensation chemistry over magnesia and zirconia
[11] ZHANG T (张媞). Synthesis and properties of cobalt-lanthanum supported on silica[J]. Journal of Molecular Catalysis A: Chemical,
based perovskite materials[D]. Zhengzhou: North China University 2010, 333(1/2): 85-93.
of Water Resources and Electric Power (华北水利水电大学), 2018. [27] ESSEHAITY A, ELHAIZ D, AMAN D, et al. Oxidative coupling of
[12] KUHN J N, OZKAN U S. Surface properties of Sr- and Co-doped bio-alcohols mixture over hierarchically porous perovskite catalysts
LaFeO 3[J]. Journal of Catalysis, 2008, 253(1): 200-211. for sustainable acrolein production[J]. RSC Advances, 2021, 11(46):
[13] TESQUET G , FAYE J, HOSOGLU F, et al. Ethanol reactivity over 28961-28972.
La 1+xFeO 3+δ perovskites[J]. Applied Catalysis A: General, 2016, 511: [28] XING Y R, YAN B, YUAN Z F, et al. Mesoporous tantalum phosphates:
141-148. Preparation, acidity and catalytic performance for xylose dehydration
[14] WANG J( 王骏 ). Photocatalytic CO 2 reduction of BaCeO 3[D]. to produce furfural[J]. RSC Advances, 2016, 6(64): 59081-59090.

235 236 237 238 239 240 241 242 243 244 245