莊永兵,工學(xué)博士,中國科學(xué)院過程工程研究所研究員、博士生導(dǎo)師、中國科學(xué)院大學(xué)崗位教師。主要研究方向?yàn)楦吣蜔峋酆衔铮ㄈ缇埘啺罚┑脑O(shè)計與制備、聚合物膜材料的制備及應(yīng)用(氣體分離膜、介電薄膜、光學(xué)薄膜等)。2008年6月畢業(yè)于湖北省化學(xué)研究院,獲高分子化學(xué)與物理碩士學(xué)位(導(dǎo)師為范和平研究員)。2011年6月畢業(yè)于四川大學(xué)高分子科學(xué)與工程學(xué)院(高分子材料工程國家重點(diǎn)實(shí)驗(yàn)室),獲高分子科學(xué)與工程博士學(xué)位(導(dǎo)師為顧宜教授)。2011年7月開始在湖南文理學(xué)院工作;2013年01月至2015年01在韓國漢陽大學(xué)(Hanyang University)從事博士后研究工作(合作導(dǎo)師為Young Moo Lee教授及Michael D. Guiver教授);2015年02月至2015年12月在加拿大拉瓦爾大學(xué)(Laval University)從事博士后研究工作(合作導(dǎo)師為Denis Rodrigue教授及Serge Kaliaguine教授);2016年04月受日本學(xué)術(shù)振興會(JSPS)資助在日本東京工業(yè)大學(xué)(Tokyo Institute of Technology)任外國人特別研究員(合作導(dǎo)師為Shinji Ando教授),曾擔(dān)任多家高新技術(shù)企業(yè)技術(shù)顧問,為中國科學(xué)院大學(xué)《膜分離科學(xué)與技術(shù)》主講教師,中國電工技術(shù)學(xué)會高級會員、中國化學(xué)會會員、中國化工學(xué)會會員、中國電工技術(shù)學(xué)會絕緣材料與絕緣技術(shù)專委會委員、《膜科學(xué)與技術(shù)》通訊編委。在《Progress in Polymer Science》、《Nature communications》、《Macromolecules》、《Science China Materials》、《Journal of membrane science》、《Chemical Communications》、 《Polymer Chemistry》、《Polymer》等雜志上發(fā)表論文30多篇,獲授權(quán)專利10多項;參編著作一部。相關(guān)研究成果被眾多綜述期刊正面引用和評價(例如Chemical Reviews,2018,118(12): 5871-5911; Chemical Reviews,2018,118(18): 8655-8769;Progress in Polymer Science,2015,43: 1-32;Progress in Polymer Science,2019,91:80-125;Progress in Materials Science,2019,102: 222-295)。
主要論文:
[1] Zhang Y, Lee WH, Seong JG, Dai J, Feng S, Wan Y, et al. Effect of structural isomerism on physical and gas transport properties of Tr?ger''''''''s Base-based polyimides. Polymer. 2022;239:124412.
[2] Li X, Zhuang Y, Ran Q, Liu X. Oxidative evolution of Z/E-diaminotetraphenylethylene. Physical Chemistry Chemical Physics. 2022.
[3] Li X, Zhou L, Cheng Z, Ran Q, Wang X, Zhuang Y, et al. Synthesis of tautomerization-inhibited diamino substituted tetraphenylethene derivatives with different mechanochromisms: the vital role of chlorine. Materials Chemistry Frontiers. 2021;5:2387-98.
[4] Chen N, Wang HH, Kim SP, Kim HM, Lee WH, Hu C, et al. Poly(fluorenyl aryl piperidinium) membranes and ionomers for anion exchange membrane fuel cells. Nat Commun. 2021;12.
[5] Li S, Qi B, Luo J, Zhuang Y, Wan Y. Ultrafast selective adsorption of pretreatment inhibitors from lignocellulosic hydrolysate with metal-organic frameworks: Performance and adsorption mechanisms. Separation and Purification Technology. 2021;275.
[6] Dai J, Zhang Y, Wang G, Zhuang Y. Structural architectures of polymer proton exchange membranes suitable for high-temperature fuel cell applications. Science China-Materials. 2021.
[7] Yang C, Xu R, Tang S, Zhuang Y, Luo L, Liu X. Free H-Bonding Interaction Sites in Rigid-Chain Polymers and Their Filling Approach: A Molecular Dynamics Simulation Study. Advanced Theory and Simulations. 2021;4.
[8] Zhang Y, Lee WH, Seong JG, Bae JY, Zhuang Y, Feng S, et al. Alicyclic segments upgrade hydrogen separation performance of intrinsically microporous polyimide membranes. J Membr Sci. 2020;611.
[9] Hu X, Lee WH, Zhao J, Bae JY, Kim JS, Wang Z, et al. Troger''''''''s Base (TB)-containing polyimide membranes derived from bio-based dianhydrides for gas separations. J Membr Sci. 2020;610.
[10] Hu X, Lee WH, Zhao J, Kim JS, Wang Z, Yan J, et al. Thermally rearranged polymer membranes containing highly rigid biphenyl ortho-hydroxyl diamine for hydrogen separation. J Membr Sci. 2020;604.
[11] Zhang D, Seong JG, Lee WH, Ando S, Wan Y, Lee YM, et al. Effects of sulfonate incorporation and structural isomerism on physical and gas transport properties of soluble sulfonated polyimides. Polymer. 2020;191.
[12] Zhuang Y, Seong JG, Lee YM. Polyimides containing aliphatic/alicyclic segments in the main chains. Prog Polym Sci. 2019;92:35-88.
[13] Zhuang Y, Orita R, Fujiwara E, Zhang Y, Ando S. Colorless Partially Alicyclic Polyimides Based on Troger''''''''s Base Exhibiting Good Solubility and Dual Fluorescence/Phosphorescence Emission. Macromolecules. 2019;52:3813-24.
[14] Zhuang Y, Ando S. Evaluation of free volume and anisotropic chain orientation of Troger''''''''s base (TB)-based microporous polyimide/copolyimide membranes. Polymer. 2017;123:39-48.
[15] Zhuang Y, Seong JG, Do YS, Lee WH, Lee MJ, Guiver MD, et al. High-strength, soluble polyimide membranes incorporating Troger''''''''s Base for gas separation. J Membr Sci. 2016;504:55-65.
[16] Zhuang Y, Seong JG, Do YS, Lee WH, Lee MJ, Cui Z, et al. Soluble, microporous, Troger''''''''s Base copolyimides with tunable membrane performance for gas separation. Chem Commun. 2016;52:3817-20.
[17] Zhuang Y, Seong JG, Lee WH, Do YS, Lee MJ, Wang G, et al. Mechanically Tough, Thermally Rearranged (TR) Random/Block Poly(benzoxazole-co-imide) Gas Separation Membranes. Macromolecules. 2015;48:5286-99.
[18] Cui Z, Hassankiadeh NT, Zhuang Y, Drioli E, Lee YM. Crystalline polymorphism in poly(vinylidenefluoride) membranes. Prog Polym Sci. 2015;51:94-126.
[19] Wang G, Lee KH, Lee WH, Kang NR, Shin DW, Zhuang Y, et al. Soluble sulfonated polybenzothiazoles containing naphthalene for use as proton exchange membranes. J Membr Sci. 2015;490:346-53.
[20] Seong JG, Zhuang Y, Kim S, Do YS, Lee WH, Guiver MD, et al. Effect of methanol treatment on gas sorption and transport behavior of intrinsically microporous polyimide membranes incorporating Troger''''''''s base. J Membr Sci. 2015;480:104-14.
[21] Zhuang Y, Seong JG, Do YS, Jo HJ, Lee MJ, Wang G, et al. Effect of Isomerism on Molecular Packing and Gas Transport Properties of Poly(benzoxazole-co-imide)s. Macromolecules. 2014;47:7947-57.
[22] Zhuang Y, Seong JG, Do YS, Jo HJ, Cui Z, Lee J, et al. Intrinsically Microporous Soluble Polyimides Incorporating Troger''''''''s Base for Membrane Gas Separation. Macromolecules. 2014;47:3254-62.
[23] Wang G, Lee KH, Lee WH, Shin DW, Kang NR, Cho DH, et al. Durable Sulfonated Poly(benzothiazole-co-benzimidazole) Proton Exchange Membranes. Macromolecules. 2014;47:6355-64.
[24] Zhuang Y, Gu Y. Molecular Packing in Crystalline Domains of Unsymmetrical Poly(benzoxazole-imide): Investigation using Modeling of a Model Compound. J Macromol Sci B. 2013;52:1603-12.
[25] Zhuang Y, Gu Y. Poly(benzoxazole-amide-imide) copolymers for interlevel dielectrics: interchain hydrogen bonding, molecular arrangement and properties. Journal of Polymer Research. 2013;20.
[26] Zhuang Y, Liu X, Gu Y. Molecular packing and properties of poly(benzoxazole-benzimidazole-imide) copolymers. Polymer Chemistry. 2012;3:1517-25.
[27] Zhuang Y, Gu Y. Probing structural evolution of the poly(amic acid) containing benzoxazole moieties in backbone during thermal imidization. Journal of Polymer Research. 2012;19.
[28] Zhuang Y, Gu Y. Novel Poly(benzoxazole-etherimide) Copolymer for Two-Layer Flexible Copper-Clad Laminate. J Macromol Sci B. 2012;51:2157-70.
申請專利:
[1]一種含朝格爾堿基芳香二羧酸及其制備方法:CN202111128010.X[P]. 2021-11-30.
[2]一種二胺單體及其制備方法和應(yīng)用:CN202110982464.7[P]. 2021-11-23.
[3]一種低介電、低導(dǎo)熱苯并環(huán)丁烯側(cè)基交聯(lián)型自具微孔聚酰亞胺薄膜的制備方法:CN202110663689.6[P]. 2021-09-03.
[4]一種含朝格爾堿基聚苯并咪唑及其磷酸摻雜高溫質(zhì)子交換膜的制備方法:CN202110662702.6[P]. 2021-11-02.
[5]一種含朝格爾堿基二酐的制備方法:CN202111006640.X[P]. 2021-11-19.
[6]一種含冠醚共聚型聚酰亞胺及其磷酸摻雜質(zhì)子交換膜的制備方法:CN202110662705.X[P]. 2021-08-31.
[7]一種燃料電池用耐高溫高透氣性磺化微孔聚合物及其鉑碳復(fù)合膜的制備方法:CN202010195095.2[P]. 2020-05-22.
[8]一種半芳香型聚酰亞胺、其制備方法、用途和包含其的氣體分離膜:CN201910979710.6[P]. 2019-12-24.
[9]一種耐高溫磺化聚苯并噻唑酰亞胺質(zhì)子交換膜及制備方法:CN201910119096.6[P]. 2019-06-14.
[10]一種含朝格爾堿基二酐的制備方法:CN201611040557.3[P]. 2017-05-31.
[11]聚酰亞胺氣體分離膜及其制備方法和應(yīng)用:CN201610495759.0[P]. 2016-11-23.
[12] 3D打印耗材生產(chǎn)裝置:CN201420681950.0[P]. 2015-05-13.
[13]實(shí)現(xiàn)連續(xù)超聲合成MBS的裝置:CN201420822512.1[P]. 2015-06-17.
[14]提高M(jìn)BS性能的合成方法及裝置:CN201410808323.3[P]. 2015-04-08.
[15]高性能可生物降解高分子材料及其制備方法:CN201410425213.9[P]. 2014-12-03.
[16]耐熱高透明性聚酰亞胺薄膜的制備方法:CN201410024241.X[P]. 2014-04-30.
[17]環(huán)氧擴(kuò)鏈劑及其制備方法:CN201410425211.X[P]. 2014-11-19.
[18]一種高粘接無膠型撓性覆銅板的制備方法:CN201310071083.9[P]. 2013-05-15.
[19]無卷曲高粘接無膠型撓性覆銅板的制備方法:CN200910167863.7[P]. 2010-04-14.
[20]一種馬來酰亞胺封端型聚酰亞胺樹脂的制備方法:CN200910148857.7[P]. 2009-12-23.
[21改性馬來酰亞胺封端型聚酰亞胺樹脂組合物及其應(yīng)用:CN200710053374.X[P]. 2008-02-13.
[22]聚酰亞胺熱固樹脂的制備和在二層法撓性覆銅板上的應(yīng)用:CN200710053151.3[P]. 2008-03-26.