发布日期:2024-04-27 浏览次数:次
个人简介 学习工作经历:2005.09---2009.07 青岛理工大学 交通工程 学士2009.09---2014.06 浙江工业大学 应用化学 博士2014.07---2017.01 浙江工业大学 机械工程流动站 博士后2017.02---2019.12 浙江工业大学 化学工程学院 讲师2020.01---至今 浙江工业大学 化学工程学院 副研究员研究方向及成果:新型共轭聚合物的设计合成、电致变色材料及器件、聚合物基复合材料、纳米材料的制备及功能化等。主持国家自然科学基金青年项目1项,省基金探索项目1项,校基金重点项目1项,横向课题6项,;以第一作者或通讯作者在Chem. Eng. J.、Small、ACS Appl. Mater. Interfaces、J. Mater. Chem. C、Electrochim. Acta、Nanotechnology等SCI期刊上发表论文30篇(其中TOP100期刊13篇),授权中国发明专利39件。 教学与课程 本科生课程:《化工专业英语与文献检索》 研究生课程:《论文写作指导》、《有机光电功能材料及应用》 育人成果 本科生培养:指导4名本科生获优秀毕业论文;指导1名本科生参加全国大学生节能减排社会实践与科技竞赛获国家三等奖。研究生培养:指导多名研究生获国家奖学金、省级优秀毕业生、校级优秀毕业生,指导研究生获第八届、第九届、第十届中国研究生能源装备创新设计大赛二等奖1项、三等奖2项,指导研究生获首届全国大学生低碳循环科技大赛一等奖2项,指导研究生获第九届中国大学生高分子材料创新创业大赛二等奖1项,指导研究生获第八届中国研究生智慧城市技术与创意设计大赛二等奖1次,指导研究生参加浙江省“新苗人才计划”获省级立项6项,各资助1万元,指导研究生获互联网+校赛银奖,指导研究生参加校运河杯科技竞赛和节能减排竞赛多次获特等奖、二等奖和三等奖。 科研项目 1、浙江省自然科学基金探索项目,苯乙烯基三苯胺类热交联聚合物的设计制备及电致变色性能调控,LY21E030010,2021.01-2023.12,已结题,主持2、国家自然科学基金青年项目,侧链悬挂离子液体基团的三苯胺类共轭聚合物及其电致变色性质研究,51703199,2018.01-2020.12,已结题,主持3、浙江工业大学校基金重点项目,基于噻吩和三苯胺类导电聚合物电致变色器件的设计与组装,1401101002408,2015.01-2017.12,已结题,主持4、横向课题:浙江工业大学能源材料及应用国际科技合作基地玉环分基地,2023.08-2026.08,在研,主持5、横向课题:贺斯特-浙江工业大学联合研发中心,2021.09-2026.09,在研,主持6、横向课题:来斯奥-浙江工业大学联合研发中心,2021.07-2024.07,在研,主持7、横向课题:橡胶阻尼片研制,2020.10-2021.03,已结题,主持8、横向课题:抗病毒原料药及关键中间体研究,2017/11-2020/11,90万,已结题,主持9、横向课题:电致变色手机后壳样品的研制,2018/04-2019/04,80万,已结题,主持 科研成果 学术论文:[1] J. Li, J. K. Cui, X. J. Lv*, L. Zhang, M. A. Xia, J. C. Dong, M. Ouyang, and C. Zhang*, Dual Polymer Complementarity Induced Truly Black Electrochromic Film and the Construction of Intelligent Eye-Protection Filters, ACS Applied Materials & Interfaces, 2023, 15(46), 53984–53995.[2] M. F. Shao, J. C. Dong, Z. Ge, R. Q. Ge, Y. Ge, X. J. Lv, M. Ouyang, C. Zhang, Flexible PEDOT/NiO@nickel foam composites materials for high-performance supercapacitors, Journal of Polymer Science, 2023, 61(24), 3343-3352.[3] M. F. Shao, J. C. Dong, X. J. Lv*, J. K. Cui, C. J. Zhou, D. S. Wright*, M. Ouyang, C. Zhang*, Multicolor electrochromic polymers based on butterfly-shaped monomers for the visualization of energy storage, Electrochimica Acta, 2023, 466, 143071.[4] M. F. Shao, D.W. Ji, Z. F. Xu, J. C. Dong, X. J. Lv, M. Ouyang, Y. K. Lv**, D. S. Wright***, C. Zhang*, High-performance electrochromic supercapacitor based on polyoxotitanates/conjugated polymer hybrid films for visualization for the energy status, Journal of Power Sources, 2023, 581, 233490.[5] J. Li, L. Zhang, J. K. Cui, X. J. Lv,* M. L. Feng, M. Ouyang, Z. X. Chen, D. S. Wright,* and C. Zhang*, Hydrogen-Bonding Induced Crosslinked Polymer Network for Highly Stable Electrochromic Device and a Construction Strategy for Black-Bilayer Electrochromic Film, Small, 2023, 19(45), 2303359.[6] X. J. Lv, M. F. Shao, X. C. Zhu, L. B. Xu, M. Ouyang, C. J. Zhou, J. C. Dong, and C. Zhang*, Thermally Cross-Linked Copolymer for Highly Transparent to Multicolor-Showing Electrochromic Materials, ACS Applied Polymer Materials, 2023, 5(5), 3595–3603.[7] X. J. Lv, X. C. Zhu, L. Zhang, M. Ouyang, M. A. Xia, C. Y. Liu, C. Zhang*, Highly Transparent to Red/Green/Blue Photo-crosslinkable Polymer for Patterned Electrochromic Device, Journal of Materials Chemistry C, 2023, 11, 5490-5497.[8] X. J. Lv*, H. F. Xu, Y. Y. Yang, M. Ouyang, M. A. Xia, C. Y. Liu, D. S. Wright, and C. Zhang*,Flexible laterally-configured electrochromic supercapacitor with feasible patterned display. Chemical Engineering Journal, 2023, 458, 141453.[9] M. F. Shao, X. J. Lv*, C. J. Zhou, M. Ouyang, X. C. Zhu, H. F. Xu, Z. S. Feng,D. S. Wright, and C. Zhang*, A colorless to multicolored triphenylamine-based polymer for the visualization of high-performance electrochromic supercapacitor. Solar Energy Materials and Solar Cells, 2023, 251, 112134.[10] J. Li, X. J. Lv*, L. Zhang, M. L. Feng , M. Ouyang , C. Y. Liu , M. A. Xia, C. Zhang**, Multiple stimuli-responsive electropolymerized polymer based on quinacridone dye via breaking conjugated structure strategy. Dyes and Pigments,2022, 207, 110689.[11] X. J. Lv,* J. Li, L. Zhang, M. Ouyang, A. Tameev, A. Nekrasov, G. Kim, C. Zhang*, High-performance electrochromic supercapacitor based on quinacridone dye with good specific capacitance, fast switching time and robust stability, Chem. Eng. J., 2022,431, 133733.[12] X. J. Lv,* J. Li, L. B. Xu, X. C. Zhu, A. Tameev, A. Nekrasov, G. Kim, H. F. Xu, C. Zhang*, Colorless to Multicolored, Fast Switching, and Highly StableElectrochromic Devices Based on Thermally Cross-Linking Copolymer, ACS Appl. Mater. Interfaces, 2021, 13, 35, 41826-41835.[13] X. J. Lv, L.X. Zha, L. Qian, X. J. Xu, Q. Bi, Z. Y. Xu, D. S. Wright, C. Zhang,Controllable fabrication of perylene bisimide self-assembled film and patterned all-solid-state electrochromic device, Chem. Eng. J., 2020, 386, 123939. [14] X.J. Lv, X. J. Xu, Y. J. Zhang, D. S Wright, Y. F. Zhang and C. Zhang, Highly transparent TiO2 nanowires as charge-balancing layers for assembling electrochromic devices: effect of thickness on electrode potentials and electrochromic performance, Nanotechnology, 2020, 31, 355201. [15] X. J. Lv, Y. Y. Yang, L. B. Xu, J. Li, Z. Y. Xu, R. Zhu, D. S. Wright, C. Zhang, An all-solid-state polymeric electrochromic device based on two well-matched electrodes with fast switching time and excellent cycling stability, Reactive and Functional Polymers, 2020, 156,104737.[16] X. J. Lv, L. B. Xu, L. Qian, Y. Y. Yang, Z. Y. Xu, J. Li, C. Zhang, A Conjugated Copolymer Bearing Imidazolium-based Ionic Liquid: Electrochemical Synthesis and Electrochromic Properties, Chinese Journal of Polymer Science, 2020, 39(5), 537-544[17]L. Qian, X. J. Lv,* M. Ouyang, A. Tameev, Q. Bi, L. X. ZHang, X. J. Xu and C. Zhang*, The influence of pendent anions on electrochemical and electrochromic properties of thiophene-triphenylamine-based polymeric ionic liquids, J. Electrochem. Soc., 2020, 167, 066506.[18]X. J. Lv, Q. Bi, A. Tameev, Y. J. Zhang, L. Qian, M. Ouyang, C. Zhang, A new green-to-transmissive polymer with electroactive poly(3,4-ethylene dioxythiophene):poly(styrene sulfonate) as an interface layer for achieving high-performance electrochromic device, J Polym Sci. 2020, 58, 937-947. [19] X. J. Lv, C. H. Huang, A. Tameev, L. Qian, R. Zhu, K. Katin, M. Maslov, A.r Nekrasov, C. Zhang, Electrochemical polymerization process and excellent electrochromic properties of ferrocene-functionalized polytriphenylamine derivative,Dyes and Pigments, 2019, 163, 433-440. [20] L. Qian, X. J. Lv,* M. Ouyang, A. Tameev, K. Katin, M.l Maslov, Q. Bi, C. H. Huang, R. Zhu, and C. Zhang*, Fast switching properties and ion diffusion behavior of polytriphenylamine derivative with pendent ionic liquid unit, ACS Appl. Mater. Interfaces,2018, 10, 32404−32412.[21] X. J. Lv, W. J. Li, M. Ouyang, Y. J. Zhang, D. S. Wright* and C. Zhang*, Polymeric electrochromic materials with various donor-acceptor structures, J. Mater. Chem. C, 2017, 5, 12. [22] X. J. Lv, S. M. Yan, Y. Y. Dai, M. Ouyang*, Y. Yang, P. Y. Yu and C. Zhang*, Ion diffusion and electrochromic performance of poly(4,4’,4’’-tris[4-(2-bithienyl)phenyl]amine) based on ionic liquid as electrolyte. Electrochim. Acta, 2015, 186, 85. [23] X. J. Lv, J. W. Sun, B. Hu, M. Ouyang*, Z. Y. Fu, P. J. Wang, G. F. Bian and C. Zhang*, Effective process to achieve enhanced electrochromic performances based on poly(4,4’,4’’-tris[4-(2-bithienyl)pheny]amine)/ZnO nanorod composites. Nanotechnology, 2013, 24, 265705.[24] X. J. Lv, B. Hu, J. W. Sun, M. Ouyang*, C. H. Yu, Z. Y. Fu and C. zhang*. Electrochemical fabrication of poly(1,4-bis(2-thienyl)-benzene)/ZnO nanoridge composite film with enhanced electrochromic performance. J. Electrochem. Soc., 2013, 160 (2), H87. [25] X. J. Lv, J. W. Sun, P. J. Wang, Q. C. Wu, M. Ouyang*, S. B. Huang, Y. Yang and C. Zhang*. A core–shell composite of porous ZnO nanosheets and a multichromic conducting polymer: enhanced electrochromic performances. New J. Chem., 2014, 38, 2400. [26] 欧阳密,朱睿,吕晓静*,曲星星,李维军,李林,吕耀康,张诚*,多色显示电致变色聚合物叠层复合薄膜的可控制备,高等学校化学学报, 2019, 40(3), 576-582. [27] 吕晓静,于朋飞,欧阳密,钱亮,闫拴马,金晓强,张诚*,石墨烯-ITO复合电极对聚苯胺薄膜电致变色性质的影响,高等学校化学学报,2017,38(4),694-700.[28] 边高峰,胡彬,欧阳密,王萍静,吕晓静*,戴玉玉,张诚*,多色显示树枝状聚(3,6-双噻吩咔唑)及其共聚物的电化学和电致变色性能,物理化学学报,2015, 31 (10), 1888-1894. 授权发明专利:[1] 吕晓静;许浩飞;张诚,一种一体式电致变色器件及其制备方法,ZL 202110901358.1, 2023. 11. 10.[2] 张诚;冯振帅;吕晓静;孙峰;一种多功能水性阻尼涂料及其制备方法,ZL 202210928090.5,2023. 09. 08.[3] 邵明发;吕晓静;张诚;董俊成;崔建坤;石煜峰;何阳;一种基于9-苯基-咔唑的噻吩类导电聚合物双功能电极材料及其制备方法和应用,ZL 202211649631.7, 2023. 07. 28.[4] 吕晓静;李锦;张诚;徐丽斌;张凌;一种基于喹吖啶酮-联二噻吩的橙红色-绿色显示电致变色材料及其制备方法,ZL 202010836545.1, 2023. 06. 09.[5] 张诚;李锦;吕晓静;许志怡;张凌;一种基于喹吖啶酮的低驱动电压电致变色材料及其制备方法,ZL 202010837106.2, 2023. 06. 09.[6] 吕晓静;李锦;张诚;杨园园;张凌;一种喹吖啶酮-噻吩衍生物及其制备方法与应用,ZL 202010866773.3, 2023. 06. 02.[7] 李锦;吕晓静;张诚;一种基于喹吖啶酮的双功能电致变色材料及其制备方法,ZL 202111480433.8, 2022. 12. 30.[8] 张诚;张同喜;吕晓静;孙峰;一种叠层复合阻尼片材及其制备方法,ZL 201910229037.4, 2022. 01. 14.[9] 张诚;许志怡;吕晓静;钱亮;黄从惠;聚(N,N-二苯基-4-(2,5-二甲基-1H-吡咯-1-基)苯胺)的应用及制备,ZL 201910653201.4, 2022. 06. 17.[10]吕晓静;徐丽斌;张诚;杨园园;一种无色-有色、高对比度的聚合物基电致变色器件,ZL 202010332911.X, 2022. 10. 11.[11]吕晓静;许志怡;张诚;基于P(SPMA-MMA)水凝胶电解质的电致变色柔性器件及其制备方法及应用,ZL 202110036765.0, 2022. 09. 23.[12]张诚,徐丽斌,吕晓静,杨园园,一种热交联功能化的三苯胺类聚合物及其制备方法与应用,ZL 201911332283.9, 2022. 05. 24.[13]欧阳密,胡旭明,邵雄超,吕晓静,陈璐,张诚,一种酞菁铜/聚苯胺复合薄膜及其制备方法与应用,ZL201910446795 .1, 2021. 04. 06.[14]张诚,徐欣佳,吕晓静,钱亮,一种聚合物基导电油墨及其电致变色器件,ZL 201910817447.0, 2022. 03. 18.[15]张诚,黄从惠,吕晓静,钱亮,朱睿,毕茜,徐欣佳,查丽霞,一种 (E) -4-(二茂铁压甲基氨基)-N, N-二苯基苯胺聚合物的应用,ZL 201811005847.3, 2022. 03. 18.[16]张诚,杨园园,吕晓静,徐欣佳,一种高性能全固态聚合物电致变色器件及其制备方法,ZL 201910904099.0, 2022. 01. 14.[17]吕晓静,查丽霞,张诚,钱亮,徐欣佳,毕茜,一种TiO2 纳米颗粒吸附苝酰亚胺衍生物薄膜及其作为电致变色材料的应用,ZL 201910520078.9, 2021. 12. 31[18]张诚,张同喜,吕晓静,孙峰,烯碳高防火性能阻尼材料及其制备方法与应用,ZL201910409534.2, 2021. 07. 27.[19]吕晓静,朱睿,张诚,徐欣佳,欧阳密,一种基于PEDOT: PSS的高稳定性电致变色器件的制备方法,ZL201811559704.7,2021. 06. 15.[20]张诚,查丽霞,吕晓静,钱亮,徐欣佳,毕茜,一种苝酰亚胺衍生物自组装薄膜及其制备方法与应用,ZL201811635113.3,2021. 06. 08.[21]吕晓静,朱睿,徐欣佳,张诚,一种PTBTPA/PEDOT聚合物叠层复合薄膜及其制备与应用,ZL201811609376.7, 2021. 06. 08.[22]吕晓静,朱睿,张诚,徐欣佳,欧阳密,一种基于PEDOT: PSS的高稳定性电致变色器件的制备方法,ZL201811559704.7, 2021. 06. 15.[23]吕晓静,钱亮,张诚,黄从惠,朱睿,一种基于咪唑型离子液体修饰的三苯胺类衍生物及其制备方法与应用,201811002876.4,2018. 08. 30.[24]张诚,查丽霞,吕晓静,钱亮,徐欣佳,毕茜,一种苝酰亚胺衍生物自组装薄膜及其制备方法与应用,ZL201811635113.3,2021. 06. 08.[25]张诚,张同喜,吕晓静,孙峰,一种交联型宽温域水性阻尼涂料及其制备,ZL201811488902.9,2021. 05. 11.[26]张诚,钱亮,吕晓静,黄从惠,毕茜,胡旭明,邵熊超,一种基于咪唑型离子液体修饰的三苯胺类衍生物的材料及其制备方法与应用,ZL201810745981.0,2021. 04. 06.[27]张诚,张同喜,孙峰,吕晓静,一种超低烟密度橡胶阻尼片及其制备方法,ZL201910228202.4,2021. 04. 06.[28]张诚,徐丽斌,吕晓静,毕茜,一种提高聚合物电致变色薄膜循环稳定性的方法,ZL201910818832.7,2021. 02. 02.[29]张诚,于朋飞,吕晓静,欧阳密,吕耀康,基于导电聚合物的固体电解质电致变色柔性器件的制备,ZL201510810819.9,2018..10. 30.[30]张诚,闫拴马,吕晓静,欧阳密,金晓强,姜慧虹,凝胶状的聚合物电解质以及基于导电聚合物的固态电致变色器件的制备方法,ZL201510108601.9, 2017. 12. 05.[31]张诚,闫拴马,吕晓静,欧阳密,戴玉玉,蔡志威,导电聚合物石墨烯复合电致变色薄膜及其制备方法,ZL201510296894.8,2017.06.13.[32]欧阳密,张诚,于朋飞,吕晓静,吕耀康,一种咔唑-噻吩类共聚物及其应用,ZL201510122579.3,2017.04.12.[33]张诚,占玲玲,欧阳密,孙璟玮,吕晓静,一种二苯乙烯腈类衍生物及其制备方法和应用,ZL201510428702.4,2017.07.28.[34]张诚,占玲玲,欧阳密,孙璟玮,吕晓静,一种二苯乙烯衍生物及其制备方法和应用,ZL201510514340.0, 2017.04.12.[35]张诚,占玲玲,欧阳密,孙璟玮,吕晓静,一种三苯胺类衍生物及其制备方法和应用,ZL 201510515309.9,2017.04.12.[36]张诚,占玲玲,欧阳密,孙璟玮,吕晓静,一种二苯乙烯衍生物及其制备方法和应用,ZL201510514340.0,2017.04.12.[37]张诚,黄森彪,吕晓静,欧阳密,戴玉玉,杨媛,一种反蛋白石结构导电聚合物薄膜的制备方法,ZL201410465530.3,2017.01.25.[38]欧阳密,吕晓静,张诚,胡彬,黄军,一种聚合物纳米管的制备方法,ZL 201210032617.2,2015.01.28.[39]欧阳密,黄军,张诚,吕晓静,张玉建,一种雪花状ZnO的制备方法,ZL201210051918.X,2014.06.11. 参加学术会议[1] X. J. Lv, C. Zhang*,Electorchromic Conjugated Polymers and Devices Utilizing Ionic Liquids, The 13th International Meeting On Electorchromism. Chiba University, Japan, 2018. 08. 27-31, Poster.[2] X. J. Lv, B. Hu, M. Ouyang *, Z Y Fu, J W Sun and C Zhang*, Organic Luminescent Molecule/ZnO Nanocomposite Film with Colors Tuning, The 11th China International NanoScience and Technology Symposium, Kunming, 2012. 10. 21-25, Poster. (SCI 论文)[3] M. Ouyang, X. J. Lv, B. Hu, G. H. Wang and C. Zhang*, Multicolor and Fast Electrochromic P(DTB-EDOT)/ZnO Nanocomposite Film, International Conference on Nanoscience & Technology, Beijing, 2011.09, Poster. (SCI 论文)[4] 吕晓静, 徐欣佳, 朱睿, 张诚,高稳定性电致变色器件的结构设计与性能分析,第四届全国电致变色研讨会, 深圳2019.08.15-17。(Oral lecture)[5] 吕晓静, 张诚,基于离子液体电解质的共轭聚合物电致变色材料及器件,第三届全国电致变色研讨会, 北京2017.11.04-07。(Oral lecture)