手机网络赌博游戏-网络赌博代理有吗-菲律宾太子娱乐城

魏毅教授

    魏毅，華裔美籍復(fù)合材料知名專(zhuān)家。1984, 1987四川大學(xué)高分子材料科學(xué)與工程系學(xué)士、碩士，1993加拿大滑鐵盧大學(xué)化學(xué)工程博士，美國(guó)里海大學(xué)界面科學(xué)研究所博士后。長(zhǎng)期任職于美國(guó)高科技跨國(guó)公司，2014年至今任東華大學(xué)民用航空復(fù)合材料中心特聘教授，紡織學(xué)院和材料學(xué)院博士生導(dǎo)師。美國(guó)化學(xué)會(huì)及先進(jìn)復(fù)合材料學(xué)會(huì)會(huì)員，SAMPE上海分會(huì)副會(huì)長(zhǎng)和陸上交通工具復(fù)合材料專(zhuān)業(yè)委員會(huì)主任。長(zhǎng)期從事功能高分子及纖維增強(qiáng)復(fù)合材料的研究開(kāi)發(fā)和工程化，研究方向涉及高性能復(fù)合材料樹(shù)脂體系、可重復(fù)成型可回收固塑體材料、熱固性復(fù)合材料增韌、納米復(fù)合材料、復(fù)合材料界面及界面域等方面，并成功實(shí)現(xiàn)了一批高新技術(shù)產(chǎn)品的產(chǎn)業(yè)化，產(chǎn)品應(yīng)用領(lǐng)域包括航空航天、軌道交通、船舶、新能源汽車(chē)、太陽(yáng)能等。

研究方向：

1.      高性能功能復(fù)合材料樹(shù)脂體系

2.     可重復(fù)成型可回收固塑體材料

3.     熱固性樹(shù)脂增韌及增韌機(jī)理

4.     先進(jìn)復(fù)合材料界面及界面域

5.     先進(jìn)復(fù)合材料樹(shù)脂及預(yù)浸料制造工程

榮譽(yù)及獲獎(jiǎng)情況：

1.      上海市復(fù)合材料創(chuàng)新成就獎(jiǎng)

2.     上海產(chǎn)學(xué)合作教育成果二等獎(jiǎng)

3.     中國(guó)紡織工業(yè)聯(lián)合會(huì)教學(xué)成果一等獎(jiǎng)

4.     國(guó)家科技進(jìn)步三等獎(jiǎng)

近年來(lái)承擔(dān)的主要科研項(xiàng)目：

1.      自動(dòng)鋪放用干纖維材料體系開(kāi)發(fā)與增韌機(jī)理研究

2.     T300碳纖維織物預(yù)浸料工藝優(yōu)化

3.     多功能碳纖維表面處理技術(shù)及配套高性能上漿劑開(kāi)發(fā)

4.     低溫固化HJT導(dǎo)電銀漿系列開(kāi)發(fā)

5.     復(fù)興號(hào)智能動(dòng)車(chē)組碳纖維格柵研制 

近年來(lái)發(fā)表的代表性論著、專(zhuān)利：

論文

1.      Bio-Based and Solvent-Free Epoxy Vitrimers Based on Dynamic Imine Bonds with High Mechanical Performance，Polymers，2025, 17, 571

2.      Toughening of Infusible Epoxy Resins by Core/Shell Nanoparticles Plus a Soluble Thermoplastic Polymer and Their Synergistic Mechanism at the Mesoscopic Morphological Level，ACS Applied Polymer Materials，Vol 7 Issue 5，2025

3.      Quantitative Prediction of Polymer Dielectric Constants Using an Improved Mathematic Correlation Based on Molecular Polarity Components，Journal of Polymer Science, 2024, 0:1–13

4.      Epoxy-imine vitrimer having low dielectric constant and high wave transmission efficiency for mobile communication applications, Polymer 2024, 313

5.      The effect of different cyclic substituents on the properties of recyclable acetal-containing epoxy resins，Polymer，290，2024，126561

6.      Composite Interlaminar Fracture Toughness Enhancement Using Electrospun PPO Fiber Veils Regulated by Functionalized CNTs. Polymers, 2023, 15, 3152

7.      Hemiaminal dynamic covalent networks with rapid stress relaxation, reprocessability and degradability endowed by the synergy of disulfide and hemiaminal bonds，RSC Advances, 2023, 13,  28658-28665

8.      A novel epoxy vitrimer with low dielectric constant at high-frequency, J Appl Polym Sci., 2023, 140:e53713

9.      A vanillin-derived hardener for recyclable, degradable and self-healable high-performance epoxy vitrimers based on transimination，Materials Today Communications, Volume 35, 2023, 106178

10.  Synthesis and structure-property relationship of epoxy vitrimers containing different acetal structures，Polymer，Volume 272, 2023, 125862

11.  Optimizing mechanical and thermomechanical properties of the self‐healable and recyclable biobased epoxy thermosets，Journal of Polymer Research (2023) 30:70

12.  Composite interlaminar fracture toughness imparted byelectrospun PPO veils and interleaf particles: a mechanistical comparison, Composite Structures,Volume 312, 2023, 116865

13.  Developing Easy Processable, Recyclable, and Self-Healable Biobased Epoxy Resin through Dynamic Covalent Imine Bonds, ACS Applied Polymer Materials, 2023, 5, 1, 279–289, DOI: 10.1021/acsapm.2c01501

14.  Hexachlorocyclotriphosphazene functionalized lignin as a sustainable and effective flame retardant for epoxy resins, Industrial Crops and Products, 187, Part B, 1, 2022, 115543

15.  A novel bio-based, flame retardant and latent imidazole compound-Its synthesis and uses as curing agent for epoxy resins, Journal of Applied Polymer Science, 2022, 139(44)

16.  A Quercetin-Derived Polybasic Acid Hardener for Reprocessable and Degradable Epoxy Resins Based on Transesterification, ACS Appl. Polym. Mater. 2022, 4, 8, 5708–5716

17.  Synthesis of cyclotriphosphazene-containing imidazole as a thermally latent hardener for epoxy resins and its application in carbon fiber reinforced composites, Appl Polym Sci., 2022, 139 (41)

18.  Review on intrinsically recyclable flame retardant thermosets enabled through covalent bonds, J Appl Polym Sci., 2022, 139 (27) e52493

19.  Review of reversible dynamic bonds containing intrinsically flame retardant biomass thermosets, European Polymer Journal, 173 (2022) 111263

20.  Review of intrinsically recyclable biobased epoxy thermosets enabled by dynamic chemical bonds, Polymer-Plastics Technology and Materials, 2022, 61 (16) 1740-1782, DOI: 10.1080/25740881.2022.2080559

21.  Formulating novel halogen-free synergistic flame retardant epoxy resins for vacuum assisted resin infusion composites, Journal of Donghua University (English Edition), 2022, 39(2): 120-127

22.  Effect of polymer nanoparticle morphology on fracture toughness enhancement of carbon fiber reinforced epoxy composites，Composites Part B, 2022, 234, 109749

23.  A thermal latent imidazole complex containing copper (II) as the curing agent for an epoxy-based glass fiber composite. Textile Research Journal. 2022;92(11-12):1867-1875

24.  Recyclable and reformable epoxy resins based on dynamic covalent bonds – Present, past, and future, Polymer Testing, 2021, 105-107420, doi.org/ 10.1016/j.polymertesting.2021.107420

25.  Correlating the thermomechanical properties of a novel bio-based epoxy vitrimer with its crosslink density, Materials Today Communications, 2021, doi.org/10.1016/j.mtcomm.102814

26.  Building Effective Core/Shell Polymer Nanoparticles for Epoxy Composite Toughening Based on Hansen Solubility Parameters, Nanotechnology Reviews, 2021, 10, 1183–96

27.  Solar transparent radiators based on in-plane worm-like assemblies of metal nanoparticles, Solar Energy Materials And Solar Cells, 2021,219:110796

28.  Tailoring Broad-Band-Absorbed Thermoplasmonic 1D Nanochains for Smart Windows with Adaptive Solar Modulation, ACS Applied Materials and Interfaces, 2021, 13(4)

29.  聚磷酸銨-三聚氰胺-三嗪成炭劑協(xié)同阻燃改性環(huán)氧樹(shù)脂及玻璃纖維增強(qiáng)樹(shù)脂復(fù)合材料, 復(fù)合材料學(xué)報(bào)，2021, 38(9): 2803-2813

30.  Reprocessable, Reworkable, and Mechanochromic Polyhexahydrotriazine Thermoset with Multiple Stimulus Responsiveness, Polymers 2020, 12, 2375; doi:10.3390/polym12102375

31.  Impressive epoxy toughening by a structure-engineered core/shell polymer nanoparticle, Composites Sci. and Tech., 2020, 199, 108364

32.  Interlaminar Fracture Toughness of Carbon-Fiber-Reinforced Epoxy Composites Toughened by Poly(phenylene oxide) Particles, ACS Applied Polymer Materials, 2020, 2, 8, 3114–3121

33.  A Comprehensive Study on the Mechanical Properties of Different 3D Woven Carbon Fiber-Epoxy Composites, Materials, 2020, 13(12):2765

34.  An imine-containing epoxy vitrimer with versatile recyclability and its application in fully recyclable carbon fiber-reinforced composites, Composites Sci. and Tech., 2020, 199, 108314

35.  Vanillin-based epoxy vitrimer with high performance and closed-loop recyclability, Macromolecules, 2020, 53, 621-630

36.  Welding and reprocessing of disulfide‐containing thermoset epoxy resin exhibiting behavior reminiscent of a thermoplastic, J. of Applied Polymer Sci., 2020, 10.1002, 49541

37.  不同尺度片狀氮化硼改性環(huán)氧樹(shù)脂復(fù)合材料性能研究，《航空制造技術(shù)》，2020-01

38.  A novel liquid imidazole-copper (II) complex as a thermal latent curing agent for epoxy resins, Polymer, 2019, 178:121586.

39.  The Failure Mechanism of Composite Stiffener Components Reinforced with 3D Woven Fabrics, Materials 2019, 12, 2221.

40.  Hierarchical assembly of silver and gold nanoparticles in two-dimension: Toward fluorescence enhanced detection platforms, Applied Surface Science, 2019, 476, 1072-1078

41.  A Comparative Study on Interlaminar Properties of L shaped Two Dimensional (2D) and Three Dimensional (3D) Woven Composites, Applied Composite Materials, 2019, 26:723-744.

42.  Recyclable Carbon Fiber Reinforced Polyimine Resin Composites, SAMPE Joural, 2019, Jan/Feb Issue, 20-28.

43.  Influence of graphene oxide with different oxidation levels on the properties of epoxy composites, Composite Sci. Technol., 2018, 161: 74-84.

44.  Effects of styrene-acrylic sizing on the mechanical properties of carbon fiber thermoplastic towpregs and their composites., Molecules, 2018, 23: 547.

45.  A one-component, fast-cure and economical epoxy resin system suitable for liquid molding of automotive composite parts, Materials, 2018, 11: 685.

46.  Effects of graphene-oxide-modified coating on the properties of carbon-fiber-reinforced polypropylene composites, Coating, 2018, 8: 149.

47.  Fast-curing halogen-free flame-retardant epoxy resins and their application in glass fiber-reinforced composites, Textile Research Journal, doi.org/10.1177/ 0040517518819840, 2018

48.  A Comparative Study on Interlaminar Properties of L-shaped Two-Dimensional (2D) and Three-Dimensional (3D) Woven Composites, Applied Composite Materials, doi.org/10.1007/s1044, 2018.

49.  碳纖維-氧化石墨烯/環(huán)氧樹(shù)脂復(fù)合材料的制備及表征，復(fù)合材料學(xué)報(bào)，2018，35，1691-1699.

50.  不同結(jié)構(gòu)厚截面三維機(jī)織碳纖維復(fù)合材料的彎曲性能對(duì)比,紡織學(xué)報(bào), 2017, 38(9)：66-71.

專(zhuān)利

1、   CN114853984B，一種共價(jià)鍵動(dòng)態(tài)交換催化劑的應(yīng)用以及一種可重復(fù)成型可降解回收的改性環(huán)氧樹(shù)脂，2022

2、  CN113150501B，一種用于真空灌注成型的苯并噁嗪阻燃改性環(huán)氧樹(shù)脂及制備方法，2021

3、  CN112920379B，環(huán)氧樹(shù)脂單體及其中間體、制備方法、環(huán)氧樹(shù)脂和回收方法，2021

4、  CN110734537B，一種潛伏性無(wú)鹵阻燃型環(huán)氧樹(shù)脂固化劑、環(huán)氧樹(shù)脂預(yù)浸料及碳纖維復(fù)合材料，2020

5、  CN110386907B，一種含亞胺鍵的環(huán)氧樹(shù)脂單體及其制備方法和應(yīng)用，2019

6、  CN110272686B，一種低鹵快速固化導(dǎo)電膠組合物及其制備方法，2019

7、   CN110003443B，一種可回收型環(huán)氧樹(shù)脂及其制備和回收方法，2019

8、  CN108774310B，一種改性咪唑類(lèi)環(huán)氧樹(shù)脂潛伏型固化劑、制備方法及應(yīng)用，2018

9、  CN108384191B，一種低粘度高耐熱增韌環(huán)氧樹(shù)脂組合物，2018

10、CN108384188B，一種基于工程塑料非織造布的預(yù)浸料及其應(yīng)用，2018

主要學(xué)術(shù)兼職：

國(guó)際先進(jìn)材料與制造工程學(xué)會(huì)/SAMPE上海分會(huì)副會(huì)長(zhǎng)

聯(lián)系電話(huà)：13601947468        E-MAIL：weiy@dhu   .edu.cn