伞晓广

作者: 时间:2023-04-27 点击数:

姓名:伞晓广
职称:教授、硕士研究生导师
电话:024-89383720
电子邮件:sanxiaoguang@syuct.edu.cn


教育背景:(从大学起)

1998.09——2002.07        沈阳化工大学,高分子材料科学与工程专业学士学位

2003.09——2006.03        沈阳化工大学,材料学专业硕士学位

2006.04——2010.03        日本国立富山大学,纳米新机能物质科学专业博士学位

 

工作经历:(含职称变化)
2002.07——2006.03         沈阳化工大学,助理工程师
2010.04——2013.03         日本高化学株式会社东京研究所,研究员

2013.03——2016.12         沈阳化工大学,讲师

2017.01——             沈阳化工大学,副教授

主要荣誉:

2021       入选辽宁省英才计划青年拔尖人才计划

2019       入选辽宁省百千万人才千人层次

2020         沈阳高校师德标兵

2021         辽宁省优秀共产党员

2019         辽宁省科技进步奖二等奖

2017         辽宁省技术发明二等奖


研究方向:(最多三个)
1、催化剂开发及应用:

功能纳米材料的设计、开发及其在碳一化工、工业催化领域研究

2、气敏传感器研发应用:

功能纳米材料的设计、开发及其在气敏传感器应用等领域研究

 

代表性成果:(论文、专利等)

[1] D. Meng, T.T. Qiao, G.H. Wang, Y.B. Shen, X.G. San*, Y.B. Pan, F.L. Meng, Appl. Sur. Sci. 577 (2022) 151877. JCR 1区,影响因子:7.392

[2] X.G.San, X.H.Gong, D.Meng, Anchoring Cu Species over SiO2 for Hydrogenation of Dimethyl Oxalate to Ethylene GlycolCatalysts1220221326 https://doi.org/10.3390/catal12111326 (JCR 2区,影响因子:4.501

[3] D. Meng, T.T. Qiao, G.H. Wang, Y.B. Shen, X.G. San*, R.X. Li, F.L. Meng, J. Alloys. Compd. 896 (2021) 162959. (JCR 2区,影响因子:6.371

[4] X.G. San, Y. Zhang, L. Zhang, G.S. Wang, D. Meng, J. Cui, Q. Jin, Chemosensors 10 (2022) 270. (JCR 2区,影响因子:4.229

[5] X.G. San, J. Cui, Y.X. Chu, J.H. Xu, D. Meng, Z.Y. Pan, G.S. Wang, J. Qi, Q. Jin, ChemistrySelect 7 (2022) 202202258. (JCR 3区,影响因子:2.307)

[6] X.G. San, Y. Zhang, L. Zhang, G.S. Wang, J.Q. Cui, D. Meng, Y.B. Shen, Resources Chemicals and Materials, https://doi.org/10.1016/j.recm.2022.06.005.

[7] D. Meng, R.X. Li a, L. zhang, G.S. Wang, Y. Zhang, X.G. San*, X.L. Wang, Sensors and Actuators Reports 4 (2022) 100104. (影响因子:0.73

[8] X.G. San, X.H. Gong, Y.B. Hu, Y. Hu, G.S. Wang, J. Qi, D. Meng, Q. Jin, ChemistrySelect 6 (2021) 6115 6118. (JCR 3区,影响因子:2.307)

[9] D. Meng, T.T. Qiao, G.H. Wang, X.G. San*, F.L. Meng, Mater. Lett. 299 (2021) 1130023. (JCR 2区,影响因子:3.574

[10]  X.G. San, Y.M. Lu, G.S. Wang, D. Meng*, X.G. Gong, Q. Jin, In situ growth of WO3 nanotube arrays and their H2S gas sensing properties for reduced operating temperature, Mater. Lett. 271 (2020) 127716.

[11] D. Meng, J.P. Si, M.Y. Wang, G.S. Wang, Y.B. Shen, X.G. San*, F.L. Meng, In-situ growth of V2O5 flower-like structures on ceramic tubes and their trimethylamine sensing properties, Chin. Chem. Lett. (2019), https://doi.org/10.1016/j.cclet.2019.12.021.

[12] D. Meng, J.P. Si, M.Y. Wang, G.S. Wang, Y.B. Shen, X.G. San*, F.L. Meng, One-step synthesis and the enhanced trimethylamine sensing properties of Co3O4/SnO2 flower-like structures, Vacuum 171 (2020) 1089942.

[13] X.G. San, D.Y. Liu, G.S. Wang, Y.B. Shen, D. Meng*, F.L. Meng, Investigation on trimethylamine sensing performance of PdO-decorated ZnO flower-like structures synthesized by one-step hydrothermal method, ChemistrySelect 4 (2019) 2694-2702.

[14] D. Meng, D.Y. Liu, G.S. Wang, Y.B. Shen, X.G. San*, J.P. Si, F.L. Meng, In-situ growth of ordered Pd-doped ZnO nanorod arrays on ceramic tube with enhanced trimethylamine sensing performance, Applied Surface Science 463 (2019) 348–356.

[15] D. Meng, D.Y. Liu, G.S. Wang, Y.B. Shen, X.G. San*, M. Li, F.L. Meng, Low-temperature formaldehyde gas sensors based on NiO-SnO2 heterojunction microflowers assembled by thin porous nanosheets, Sensors & Actuators: B. Chemical, 273 (2018) 418–428.

[16] X.G. San, M. Li, D.Y. Liu, G.S. Wang, Y.B. Shen, D. Meng, F.L. Meng, A facile one-step hydrothermal synthesis of NiO/ZnO heterojunction microflowers for the enhanced formaldehyde sensing properties, Journal of Alloys and Compounds 739 (2018) 260-269.

[17] X.G. San, G.D. Zhao, G.S. Wang, Y.B. Shen, D. Meng, Y.J. Zhang, F.L. Meng, Assembly of 3D flower-like NiO hierarchical architectures by 2D nanosheets: Synthesis and their sensing properties to formaldehyde, RSC Advances, 2017, 7, 3540–3549.

[18] X.G. San, G.D. Zhao, G.S. Wang, J. Qi, Q. Jin, D. Meng, Synthesis of CuO/ZnO flower-like hierarchical porous structures and investigation of their catalytic performances for dimethyl oxalate hydrogenation, China Petroleum Processing and Petrochemical Technology, 2017, 19, 40–47.

[19] D. Meng, D.Y. Liu, G.S. Wang, X.G. San, Y.B. Shen, Q. Jin, F.L. Meng, CuO hollow microspheres self-assembled with nanobars: synthesis and their sensing properties to formaldehyde, Vacuum, 2017, 14, 272–280.

[20] X.G. San, G.H. Wang, B. Liang , J. Ma, Dan Meng*, Y.B. Shen, Flower-like NiO hierarchical microspheres self-assembled with nanosheets: surfactant-free solvothermal synthesis and their gas sensing properties, J. Alloys. Compd. 636 (2015) 357–362.

[21] X.G. San, G.S. Wang, B. Liang, Y.M. Song, S.Y. Gao, J.S. Zhang, F.L. Meng, Catalyst-free growth of one-dimensional ZnO nanostructures on SiO2 substrate and in situ investigationof their H2 sensing properties, Journal of Alloys and Compounds, 2015, 622: 73-78.

[22] X.G. San, W.W. Xu, G.S. Wang, B. Ling, N.N. Hou, F.L. Meng, Facile preparation of size-controlled TiO2 nanoparticles by hot-filament metal oxide deposition method and their gas sensing properties to NO2, Functional Materials Letters, 2015, 8: 15500431-15500434.

[23] D. Meng, G.H. Wang, X.G. San*, Y.M. Song, Y.B. Shen, Y.J. Zhang, K.J. Wang, F.L. Meng, Synthesis of WO3 flower-like hierarchical architectures and their sensing properties, J. Alloys. Compd. 649 (2015) 731-738.

[24] D. Meng, G.S. Wang, X.G. San, Y.B. Shen, G.D. Zhao, Y.J. Zhang, F.L. Meng, CTAB-assisted hydrothermal synthesis of WO3 hierarchical porous structures and investigation of their sensing properties, J. Nanomater. 2015, Article ID 393205.

[25] G.H. Yang, X.G. San, N. Jiang, Y. Tanaka, X.G. Li, Q. Jin, K. Tao, F.Z. Meng, N. Tsubaki, A New Method of Ethanol Synthesis from Dimethyl Ether and Syngas in a Sequential Dual Bed Reactor with the Modified Zeolite and Cu/ZnO Catalysts. Catalysis Today, 2011, 164, 425-428.

[26] X.G. Li, X.G. San, Y. Zhang, T. Ichii, M. Meng, Y.S. Tan, N. Tsubaki, Direct synthesis of ethanol from dimethyl ether and syngas over the combined H-Mordenite and Cu/ZnO catalysts with high catalytic activity. Chem. Sus. Chem., 2010, 3, 1192-1199.

[27] Zhang Y., X.G. San, N. Tsubaki, Y.S. Tan, Novel Ethanol Synthesis Method via C1 Chemicals without Any Agriculture Feedstocks Ind. Eng. Chem. Res. 2010, 49, 5485-5488.

[28] X.G. Li, Y. Zhang, M. Meng, X.G. San, M. Takahashi, N. Tsubaki, Silicalite-1 Membrane Encapsulated Rh/Activated-Carbon Catalyst for Hydroformylation of 1-Hexene with High Selectivity to Normal Aldehyde, J. Membrane Science, 2010, 347, 220-227.

[29] [17] X.G. Li, Y. Zhang, F.Z. Meng, X.G. San, M. Meng, M. Takahashi, N. Tsubaki, Hydroformylation of 1-Hexene on Silicalite-1 Zeolite Membrane Coated Pd-Co/A.C. Catalyst Topics in Catalysis, 2010, 53, 608-614.

[30] X.G. San, Y. Zhang, W.J. Shen, N. Tsubaki, New Synthesis Method of Ethanol from Dimethyl Ether with a Synergic Effect between the Zeolite Catalyst and Metallic Catalyst, Energy & Fuels, 2009, 23, 2843–2844.

[31] San X.G., G.H. Yang, Y. Zhang, X.G .Li, N. Tsubaki, New method for ethanol synthesis via two-Stage reaction: investigation for products selectivity under various reaction temperatures, Journal of the Japan Petroleum Institute, 2009, 52, 357-358.

[32] Y. Yoneyama, X.G. San, T. Iwai, N. Tsubaki, One-step synthesis of isoparaffin from synthesis gas using hybrid catalyst with supercritical butane, Energy & Fuels, 2008, 22, 2873–2876.

 

代表性项目:

1.主持辽宁省委组织部兴辽英才计划项目,功能纳米材料结构调控及其在碳中和领域催化应用研究(XLYC200705150万,2021.1.1

2.主持辽宁省科技厅项目,高分散铜锌负载石墨烯催化剂的制备及其应用于CO2加氢合成甲醇反应性能研究(2019-ZD-0072)5万,2019年。

3.主持辽宁省教育厅项目,多级孔道复合氧化物催化材料构建及其催化二氧化碳甲烷化反应性能研究(LQ2019013)3万,2019年。

4.持国家自然科学基金青年科学基金项目,分级多孔Cu/ZnO@MOR双功能核壳催化剂的构建及其催化二甲醚与合成气一步法制备乙醇性能研究(2150313724.9万,2016年。

5.主持辽宁省教育厅科学研究一般项目,双孔Ni/沸石高效催化剂的构建及其催化CH4CO2重整反应性能研究(L20154253,2016年。

6.主持教育部留学回国人员启动基金,改性沸石催化剂与多组分负载催化剂应用于合成乙醇研究(教育司留[2014]1685)3.52014年。

7.主持浙江省农业生物资源创新中心开放基金,分级多孔Ni基高效催化剂的构建及其催化CH4CO2重整反应性能研究,32016年。

8.主持校企合作项目,高化学(江苏)化工新材料有限责任公司,煤制乙二醇工艺催化剂性能测试(No.2016210101005167

9.主持校企合作项目,青岛爱尔佳新材料股份有限公司,高温隔热涂料的开发应用研究(No.2017210101001074

10.主持校企合作项目,沈阳感光化工研究院有限责任公司,加氢催化剂性能测试(2019210101003976

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