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索習(xí)東,山西忻州人。博士。主要從事水性聚氨酯涂料、聚氨酯粘合劑、先進炭材料與器件的教學(xué)和研究工作。2020年獲中國科學(xué)院山西煤炭化學(xué)研究所材料加工工程博士學(xué)位?,F(xiàn)就職于忻州師范學(xué)院化學(xué)系,主講《物理化學(xué)》《膠體與界面化學(xué)》專業(yè)課程。


主持項目:

[1] 碳纖維表面、界面結(jié)構(gòu)調(diào)控及其光熱轉(zhuǎn)換和阻鹽性能研究,山西省科技廳,2022,8萬,主持。

[2] 纖維素基氣凝膠微結(jié)構(gòu)調(diào)控及其光熱轉(zhuǎn)換性能影響研究,山西省教育廳,2021,2萬,主持。

[3] 界面性質(zhì)對纖維素碳氣凝膠光熱轉(zhuǎn)換性能的影響研究,忻州師范學(xué)院,2020,2.5萬,主持。

代表性論文:

[1] Jie Yang, Xidong Suo*, Jingjing Zhao, et al. Carbon fiber coated by quinoa cellulose nanosheet with outstanding scaled salt self-cleaning performance and purification of organic and antibiotic contaminated water[J]. Scientific Reports, 2022, 12, 8777.

[2] Jie Yang, Xidong Suo,* Xiaorong Chen, et al. Water-light induced self-blacking system constituted by quinoa cellulose and graphene oxide for high performance of salt-rejecting solar desalination[J]. Advanced Sustainable systems, 2022, 202100350.

[3] Hongtao Qiao, Baowei Zhao, Xidong Suo*, et al. The Biochar Derived from Carp for High-Efficiency Solar Steam Generation and Water Purification[J]. Global Challenges, 2022, 6, 2100083.

[4] Xidong Suo,* Jie Yang,* Yanrong Zhang, et al. Hollow Carbon Fiber Decorated by Nano Structure Surface for High-Efficiency Water Steam Generation[J]. Advanced Sustainable systems, 2021, 202100122.

[5] Xidong Suo, Zhuo Cao, Yuxiu Yu, Liu Yaodong*, Self-Stiffening Behavior Induced by the Polymer Interface in Polyacrylonitrile and thermoplastic polyurethanes composite films[J]. Composites Science and Technology. 2020, 198, 108256.

[6] Xidong Suo, Yuxiu Yu, Zhuo Cao, Liu Yaodong*, Effect of Interlayer Interactions on the Dynamic Self-Stiffening Behaviors of Graphene Oxide Based Films[J]. Advanced materials interface, 2020, 200499.

[7] Huiqing Wei, Xidong Suo(共同一作), ChunxiangLu*, Yaodong Liu*. Comparison of the thermal stabilization behaviors of dry-Jet gel spun and dry-Jet wet spun polyacrylonitrile fibers[J]. Journal of applied polymer science, 2019, 137, 48671.

[8] Li Xiaopeng, Suo Xidong, Liu Yaodong*, Li Yonghong*. Effect of gelation time on the microstructures: mechanical properties and yclization reactions of dry-jet gel-spun polyacrylonitrile fibers[J]. New carbon materials, 2019, 34(1):9-18.

[9] Zhuo Cao, Weijie Li, Xidong Suo, Yaodong Liu*, Chunxiang Lu*. Structures and cyclization behaviors of gel-spun cellulose/polyacrylonitrile composite fbers[J]. Polymer testing, 2020, 81, 106276.

[10] Hao Jian Huiqing Wei, Xidong Suo, ChunxiangLu*, Yaodong Liu*. Highly isotactic (> 60%) polyacrylonitrile-based carbon fber: Precursor synthesis, fber spinning, stabilization and carbonization Comparison of the thermal stabilization behaviors of dry-Jet gel spun and dry-Jet wet spun polyacrylonitrile fibers[J]. Polymer, 157 (2018) 139–150.