西北大学食品科学与工程学院成立于2017年,是在2002年成立的西北大学化工学院食品工程系的基础上,汇集西北农林科技大学食品科学与工程、西北大学食品科学与工程、生命科学等相关专业的师资力量组建而成。学院现有二级学科博士点1个,一级学科硕士点1个,二级学科硕士点1个。 学院现有专职教师45人,其中教授9人,副教授21人,讲师15人,100%的教师具有博士学位,80%的教师有海外留学经历。教师队伍中有原国务院学位委员会学科评议组专家1人,享受国务院特殊津贴专家1人,教育部新世纪人才2人,陕西省“三五”人才1人,陕西省科技创新领军人才2人和陕西青年科技奖获得者2人。学院拥有“朱蓓薇院士工作站”、“陕西省食品安全风险识别控制技术研究中心”、“陕西省营养健康食品个性制造工程实验室”、“陕西省食品安全与营养健康创新转化平台”和“陕西省蜂产品工程技术研究中心”、“陕西省天然多糖资源利用工程研究中心”等科研平台...
所属部门:食品科学与工程学院
职务/职称:讲师
电子邮件:y_shu@nwu.edu.cn
个人简介:
舒羽,女,汉族,博士,硕士生导师。2017年10月毕业于大阪大学(日本),获工学博士学位。主要从事食品加工副产品、天然生物质资源的高效转化与利用研究。主讲《分析化学》、《粮油食品工艺学》、《文献检索与利用》和《食品与环境》等课程。先后在Chem. Eng. J., Sci. Total Environ., J. Power Sources, Carbohyd. Polym., Small, Nanoscale, J. Environ. Chem. Eng., Food Chem., J. Agric. Food Chem., Food Frontiers等SCI期刊发表论文20余篇,主持国家重点研发计划项目子课题、陕西省重点研发计划、陕西省基础研究计划项目等3项,参与国家自然科学基金、陕西省科技计划项目等4项。
部分研究成果:
[1] Shu Y.1 *, Qiao L.1, Geng J., Li C., Chen B., Wang Q., Uyama H. & Shen Y.*, A novel ZIF-8@cellulose composite monolithic carbon via a facile template-free strategy for selective and efficient CO2 adsorption. Chem. Eng. J., 2024, 488, 151079.
[2] Cao M.1, Shu Y. 1 *, Bai Q., Li C., Chen B., Shen Y.* & Uyama H., Design of biomass-based N, S co-doped porous carbon via a straightforward post-treatment strategy for enhanced CO2 capture performance. Sci. Total Environ., 2023, 884, 163750.
[3] Shu Y.1, Bai Q.1, Fu G., Xiong Q., Li C., Ding H., Shen Y.* & Uyama H., Hierarchical porous carbons from polysaccharides carboxymethyl cellulose, bacterial cellulose, and citric acid for supercapacitor. Carbohyd. Polym., 2020, 227, 115346-115358.
[4] Shu Y., Maruyama J., Iwasaki S., Maruyama S., Shen Y. & Uyama H., Nitrogen-doped biomass/polymer composite porous carbons for high performance supercapacitor. J. Power Sources, 2017, 364, 374-382.
[5] Shu Y., Maruyama J., Iwasaki S., Maruyama S., Shen Y. & Uyama H., Fabrication of N-doped and shape-controlled porous monolithic carbons from polyacrylonitrile for supercapacitors. RSC Adv., 2017, 7 (68), 43172-43180.
[6] Shu Y., Maruyama J., Iwasaki S., Li C., Shen Y. & Uyama H., Hierarchical activated green carbons from abundant biomass waste for symmetric supercapacitors. B. Chem. Soc. Jap., 2017, 90 (9), 1058-1066.
[7] Shu Y., Dobashi A., Li C., Shen Y. & Uyama H., Hierarchical porous carbon from greening plant shell for electric double-layer capacitor application. B. Chem. Soc. Jap., 2017, 90 (1), 44-51.
[8] Shu Y., Maruyama J., Iwasaki S., Shen Y. & Uyama H., Activated carbon monolith derived from amygdalus pedunculata shell and polyacrylonitrile for supercapacitors. B. Chem. Soc. Jap., 2017, 90 (12), 1333-1336.
[9] Wang Z., Xie Q., Wang Y., Shu Y., Li C. & Shen Y., The fixation of CO2 by epoxides over nickel-pyrazolate-based metal-organic frameworks. New J. Chem., 2020, 44, 18319-18325.
[10] Xie Q., Wang Z., Lin L., Shu Y., Zhang J., Li C., Shen Y. & Uyama H., Nanoscaled and atomic ruthenium electrocatalysts confined inside super-hydrophilic carbon nanofibers for efficient hydrogen evolution reaction. Small, 2021,17,2102160.
[11] Li H., Bai Q., Li C., Wei X., Shu Y., Chen B. & Shen Y., N-Doped Two-Dimensional Carbon Nanosheets with Micropore-Dominant Porosity for High-Performance Supercapacitors, Energy Fuels, 2022, 36(21), 13246-13255.
[12] Xie Q., Pan M., Wang Z., Si W., Zhang R., Shu Y., Sun G., Jing Q., Shen Y. & Uyama H., Enhancing the oxygen reduction activity by constructing nanocluster-scaled Fe2O3/Cu interfaces. Nanoscale, 2023, 15, 4388-4396.
[13] Xie Q., Si W., Wang Z., Shu Y., Li C., Shen Y. & Uyama H., Controlling sp3 defect density of carbon-based catalysts by defining a limiting space. Chem. Eng. J., 2023, 452, 139221.
[14] Wang Q., Zhu J., Yu F., Li Y., Zhang Y., Peng X., He D., Zhao S., Zheng W., Shang J., Li S., Wang H., Shu Y., Uyama H. & Mao G., A thermoplastic polyurethane-based composite aerogel with low shrinkage and high specific surface area enhanced by activated carbon for highly efficient oil/water separation. J. Environ. Chem. Eng., 2023, 11, 111077.
[15] Lin L., Li C., Li T., Zheng J., Shu Y. Zhang J., Shen Y. & Ren D., Plant-derived peptides for the improvement of Alzheimer’s disease: Production, functions, and mechanisms. Food Frontiers, 2023, 4(2), 677-699.
[16] Zhang J., Gao Y., Zhao M., Xu X., Xi B., Lin L., Zheng J., Chen B., Shu Y. Li C. & Shen Y., Detection of walnut oil adulterated with high-linoleic acid vegetable oils using triacylglycerol pseudotargeted method based on SFC-QTOF-MS, Food Chem., 2023, 416, 135837.
[17] Zhang J., Gao Y., Xu X., Zhao M., Xi B., Shu Y., Li C. & Shen Y., In Situ Rapid Analysis of Squalene, Tocopherols, and Sterols in Walnut Oils Based on Supercritical Fluid Chromatography-Quadrupole Time-of-Flight Mass Spectrometry, J. Agric. Food Chem., 2023, 71(43), 16371-16380.
[18] Xi B., Zhang J., Xu X., Li C., Shu Y. Zhang Y., Shi X. & Shen Y., Characterization and metabolism pathway of volatile compounds in walnut oil obtained from various ripening stages via HS-GC-IMS and HS-SPME-GC-MS, Food Chem., 2024, 435, 137547.
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