导师信息

和铭

发布时间:2022-09-26作者:出处:轻工学院责任编辑:轻工学部

姓名

和铭

性别

出生年月

1989.01

学历

博士研究生

专业

轻化工程

职称

副教授

单位

齐鲁工业大学轻工学部、绿色造纸与资源循环全国重点实验室

邮箱

heming8916@qlu.edu.cn

通讯地址

山东省济南市长清区大学路3501

个人简历:

和铭,男,博士,副教授,硕士生导师,山东省高等学校青创团队负责人,济南市高层次人才。20117月获齐鲁工业大学轻化工程专业学士学位;20172月获韩国国立江原大学(Kangwon National University)造纸工程系工学博士学位;加拿大不列颠哥伦比亚大学(University of British   Columbia)访问学者(2024.8-2025.8,合作导师:Orlando Rojas)。20179月加入齐鲁工业大学从事教学科研工作以来,主要从事生物质纳米功能材料的制备及应用及木质纤维组分功能化技术等方面的研究工作。主持国家自然科学基金、山东省自然科学基金、科教产融合培优基金、山东省科技型中小企业创新能力提升工程项目以及多项企业横向项目等;作为研究骨干参与国家重点研发计划项目、科技部国际合作项目、国家自然科学基金、韩国能源技术部等课题的研究工作。担任轻化工程本科专业课程《制浆原理与工程(双语》、《造纸原理与工程(双语)》授课骨干教师,在NPJ Clean WaterSmallDesalinationCarbohydrate     PolymersNano Research等国内外期刊发表学术论文50余篇,获批国际PCT发明专利3项,国家发明专利5项,获山东省科学技术进步奖一等奖1项,韩国工业化学会优秀论文奖1项、韩国制浆造纸工学会优秀论文发表奖1项,齐鲁工业大学高水平学术成果奖1项。韩国制浆造纸工学会会员,韩国工业化学会会员,美国TAPPI-Nano分会会员;中国化学会会员,《Green Carbon》,《世界竹藤通讯》,《中国造纸》青年编委,Polymers, Materials, KTAPPI等杂志客座编辑,Desalination, Cellulose, Carbohydrate polymers等杂志审稿人。

 

研究方向:长期致力于先进纤维素功能材料的开发及其构效关系的深入解析,系统研究低共熔溶剂功能化纳米纤维素基复合材料的构筑及关键控制要点,开发了直接控制和从分子水平上永久改变纤维素表面官能团的关键技术。面向我国“双碳”目标,利用生物质木质纤维大分子特性、聚集态结构、界面相互作用、材料本征结构等优势,通过结构调控、界面工程、微观缺陷调控、异质掺杂等方法,构建一系列新型纤维多尺度功能材料,旨在开发先进纤维素功能材料并用于能源和治理环境污染方面

 

成果简介:

近五年发表论文:

1.        He, M.* Sun, Q., Wang, Y., Ahmadreza,   G., Orlando, R. (2026). Stimuli-responsive   cellulose: from molecular engineering to macroscopic function. Trends in   Chemistry, 8, 203-217.

2.        Sun,   Q., Ma, H., Zhang, Y., Hu, Y., Wang, J., Qi, Y., Wang, Y., Yang, G., & He, M.*(2025).Ultra-strong bamboo   macrofibers via selective delignification and microwave drying for   lightweight structural composites, Industrial Crops and Products, 236,   122059.

3.        Yang, Z., Lu, Y., He, M.*   et al. (2025). Impact of cellulose nanofibril modification on the   electrochemical performance of Ti3C2Tx-based   supercapacitors. Cellulose, 32, 7131-7143.

4.        Wang, Y., Sun, Q., Yang,   G., Si, C., Zhang, J., and He, M.* (2025). Construction of N-Doped   Carbon Nanotube Confining MoC/Ni Mott–Schottky Heterojunction on Porous   Carbonized Wood for Efficient Urea-Assisted Water Splitting. Advanced   Sustainable Systems, 9, no.10: e00964.

5.        Hu, Y., Wang, Y., Sun, Q., Qi,   Y., Zhang, Y., Ji, X., Yang, G., Shi, Z., Rojas, O., & He, M.*   (2024). Interfacial modulation of Ti3C2Tx   MXene using functionalized cellulose nanofibrils for enhanced electrochemical   actuation, International Journal of Biological Macromolecules, 281(1),   136299.

6.        Wang, Y., Zhuang, Y., Yang,   G., Dong, C., * & He,   M.*   (2024). Unraveling the Dynamic Reconstruction of Active Co(IV)-O Sites on   Ultrathin Amorphous Cobalt-Iron Hydroxide Nanosheets for Efficient   Oxygen-Evolving, Small, 2404205.

7.        Zhuang, Y., Wang, Y., * Yang,   G., * Shi, Z., Zhang, Y., & He, M.* (2024). Carbonized Wood Plate   Decorated with a N‑Doped Carbon Nanomushroom Encapsulating FeNiS2/   (Co, Ni, Fe)9S8 Heteroparticle for Efficiently   Catalyzing Oxygen Evolution Reaction, ACS Applied Energy Materials, 7,   6687-6695.

8.        Wang, Y., Zhuang, Y., Hu,   Y., Kong, F., Yang, G., Rojas, O., & He, M.*   (2023). Hollow N-doped carbon nano-mushrooms encapsulated hybrid   Ni3S2/Fe5Ni4S8 particles anchored to the inner wall of porous wood carbon for   efficient oxygen evolution electrocatalysis, Nanoscale, 15,   18033-18043.

9.        Yang, Z., Wang, Y., Hu, Y.,   Zhuang, Y., Ji, X., Yang, G.,& He, M.* (2023). A morphology control   engineered strategy of Ti3C2Tx/sulfated   cellulose nanofibril composite film towards high-performance flexible   supercapacitor electrode, International Journal of Biological Macromolecules,   243, 124828.

10.    Ma, G., Zhang, Z., Chen,   J., Yang, G., & He, M.* (2023). Facile sulfation of cellulose via   recyclable ternary deep eutectic solvent for low-cost cellulose nanofibril   preparation. Nanoscale Advances, 5, 356-360.

11.  He, M.*, Li, W., Chen, J. et al.   (2022). Immobilization of silver nanoparticles on cellulose nanofibrils   incorporated into nanofiltration membrane for enhanced desalination   performance. NPJ Clean Water, 5, 64.

12.  Li, W., Wang, X., He, M.*,   et.al. (2022). Fabrication of high-performance nanofiltration membranes by   using sulfated cellulose nanofibril as the intermediate support layer, Desalination,   532, 115741.

13.  Zhang, Z., Yang, G., He, M.*, et.al. (2022). Synthesis of   Silver Nanoparticles and Detection of Glucose via Chemical Reduction with   Nanocellulose as Carrier and Stabilizer. International Journal of   Molecular Sciences, 23, 15345.

14.  Wang, Y., Yang, Z., Zhang, Z., He, M.* (2022). Corrosion-Engineered   Morphology and Crystal Structure Regulation toward Fe-Based Efficient Oxygen   Evolution Electrodes. Nanomaterials, 12, 1975.

15.  Li, W., Xue, Y., He, M.*, et.al. (2021). Facile Preparation and Characteristic Analysis of   Sulfated Cellulose Nanofibril via the Pretreatment of Sulfamic Acid-Glycerol   Based Deep Eutectic Solvents. Nanomaterials, 11(11), 2778.

16.  Xue, Y., Qi, L., Lin, Z.,Yang, G., He, M.* & Chen, J. (2021).  High-Strength Regenerated Cellulose Fiber   Reinforced with Cellulose Nanofibril and Nanosilica.Nanomaterials, 11(10), 2664.

17.  Yang, G.; Ma, G.; He, M.*; Ji, X.; Li, W.; Youn, H.J.;   Lee, H.L.; & Chen, J. (2021). Comparison of Effects of Sodium Chloride   and Potassium Chloride on Spray Drying and Redispersion of Cellulose   Nanofibrils Suspension. Nanomaterials, 11(2), 439.

18.  Ma, G., He, M.*, Yang, G., Ji, X., Lucian, A., & Chen,   J. (2021). A feasible   approach efficiently redisperse dried cellulose nanofibrils in water: vacuum   or freeze drying in the presence of sodium chloride. Cellulose,28, 829-842.


 

代表性研究成果:

获奖:

1.        2024年度山东省科学技术进步奖,一等奖,山东省科技厅,2024.4

2.        韩国制浆造纸工学会优秀论文发表奖,韩国制浆造纸工学会,2015.10.30

3.        韩国工业化学会优秀论文奖,韩国工业化学会,2013.5.2