主要研究纤维增强复合材料的强韧化设计、成型制造和连接技术, 参与多项爱尔兰复合材料研究中心核心科技项目、庞巴迪宇航、汉高和贝卡尔特等知名企业的科技合作项目,获得欧盟H2020玛丽-居里学者项目资助,以第一作者在 Compos. Sci. Technol.、Compos. Part. A Appl. Sci. Manuf.和 Compos. B Eng. 等期刊上发表 SCI 论文 28 篇,研究成果在汽车、航空用结构性胶黏剂、飞机机翼和整流罩内的碳纤维结构部件以及高压电悬浮绝缘子和变电站避雷器等产品中广泛应用。 代表性科研论文: 1. D. Quan et al. Co-curing bonding of carbon fibre/epoxy composite joints with excellent structure integrity using carbon fibre/PEEK tapes, Composites Science and Technology, 227 (2022) 109567 (中科院一区;IF= 8.528). 2. D. Quan et al. The development of high performance hybrid joints between epoxy composites and PEEK/PPS composites: The mode-II and mix mode-I/II fracture behaviour, Composite Structures 292 (2022) 115638 (中科院一区;IF= 5.407). 3. D. Quan* et al. On the fracture behaviour of aerospace-grade Polyether-ether-ketone composite-to-aluminium adhesive joints, Composites Communications 30 (2022) 101098 (中科院二区;IF= 6.617). 4. D. Quan* et al. Recycled carbon fibre mats for interlayer toughening of carbon fibre/epoxy composites, Materials & Design 218 (2022) 110671(中科院一区;IF= 7.991). 5. D. Quan* et al. Fatigue delamination behaviour of carbon fibre/epoxy composites interleaved with thermoplastic veils, Composite Structures,In press (中科院一区;IF= 5.407). 6. D. Quan et al. Mode-II fracture behaviour of aerospace-grade carbon fibre/epoxy composites interleaved with thermoplastic veils, Composites Science and Technology 191 (2020) 108065. (中科院一区;IF= 8.528). 7. D. Quan* et al. Significantly enhanced structural integrity of adhesively bonded PPS and PEEK composite joints by rapidly UV-irradiating the substrates, Composites Science and Technology 199 (2020) 108358 (中科院一区;IF= 8.528). 8. D. Quan et al. Improving the electrical conductivity and fracture toughness of carbon fibre/epoxy composites by interleaving MWCNT-doped thermoplastic veils, Composites Science and Technology 182 (2019) 107775 (中科院一区;IF= 8.528). 9. D. Quan et al. Effect of interlaying UV-irradiated PEEK fibres on the mechanical, impact and fracture response of aerospace-grade carbon fibre/epoxy composites, Composites Part B: Engineering 191 (2020) 107923 (中科院一区;IF= 9.078). 10. D. Quan* et al. Rapid surface activation of carbon fibre reinforced PEEK and PPS composites by high-power UV-irradiation for the adhesive joining of dissimilar materials, Composites Part A: Applied Science and Manufacturing 137 (2020) 105976. (中科院一区;IF= 7.664). 11. D. Quan et al. Interlaminar fracture toughness of aerospace-grade carbon fibre reinforced plastics interleaved with thermoplastic veils, Composites Part A: Applied Science and Manufacturing 128 (2020) 105642 (中科院一区;IF= 7.664). 12. D. Quan et al. Enhancing mode-I and mode-II fracture toughness of epoxy and carbon fibre reinforced epoxy composites using multi-walled carbon nanotubes, Materials & Design 143 (2018) 81-92 (中科院一区;IF= 7.991). 13. D. Quan* et al. The influence of interlayer/epoxy adhesion on the mode-I and mode-II fracture response of carbon fibre/epoxy composites interleaved with thermoplastic veils, Materials & Design 192 (2020) 108781(中科院一区;IF= 7.991). 14. D. Quan et al. Fracture behaviour of carbon fibre/epoxy composites interleaved by MWCNT- and graphene nanoplatelet-doped thermoplastic veils, Composite Structures 235 (2020) 111767 (中科院一区;IF= 5.407). 15. D. Quan et al. Interlaminar fracture toughness of CFRPs interleaved with stainless steel fibres, Composite Structures 210 (2019) 49-56 (中科院一区;IF= 5.407). 16. D. Quan et al. The enhancement of adhesively-bonded aerospace-grade composite joints using steel fibres, Composite Structures 198 (2018) 11-18 (中科院一区;IF= 5.407). 17. D. Quan* et al. Co-cure joining of epoxy composites with rapidly UV-irradiated PEEK and PPS composites to achieve high structural integrity, Composite Structures 251 (2020) 112595 (中科院一区;IF= 5.407). 18. D. Quan* et al. Enhancing the fracture toughness of carbon fibre/epoxy composites by interleaving hybrid meltable/non-meltable thermoplastic veils, Composite Structures 252 (2020) 112699 (中科院一区;IF= 5.407). 19. D. Quan et al. Effect of core-shell rubber (CSR) nano-particles on mechanical properties and fracture toughness of an epoxy polymer. Polymer 66 (0) (2015) 16-28 (中科院二区;IF= 4.430). 20. D. Quan et al. The intrinsic fracture property of a rubber-modified epoxy adhesive: geometrical transferability, Engineering Fracture Mechanics, 203 (2018) 240-249. (中科院二区;IF= 4.406). 21. D. Quan et al. Fracture behaviour of epoxy adhesive joints modified with core-shell rubber nanoparticles. Engineering Fracture Mechanics 182 (2017) 566-576. (中科院二区;IF= 4.406). 22. D. Quan et al. Fracture behaviour of a nano-modified structural epoxy adhesive: bond gap effects and fracture damage zone. International Journal of Adhesion and Adhesives 77 (2017) 138-150 (中科院二区;IF=3.189). 23. D. Quan et al. Mechanical and fracture properties of epoxy adhesives modified with graphene nanoplatelets and rubber particles. International Journal of Adhesion and Adhesives, 81 (2018) 21-29 (中科院二区;IF=3.189). 24. D. Quan et al. Carbon nanotubes and core-shell rubber nanoparticles modified structural epoxy adhesives, Journal of Materials Science 52 (2017) 4493-4508 (中科三区;IF= 4.22). 25. D. Quan et al. Synergistic toughening and electrical functionalization of an epoxy using MWCNTs and silane-/plasma-activated basalt fibres, Journal of Applied Polymer Science 138 (2021) 49605 (中科院三区; IF=3.125). 26. D. Quan et al. Interaction of Toughening Mechanisms in Ternary Nanocomposites. Polymer Composites 39 (2018) 3482-3496 (中科院三区;IF=3.171). 27. D. Quan et al. Damage behaviour of nano-modified epoxy adhesives subject to high stress constraint. The Journal of Adhesion 94 (2018) 387-405 (中科院三区;IF=2.917). 28.Gennaro Scarselli, D. Quan* et al. Adhesion Improvement of Thermoplastics‐Based Composites by Atmospheric Plasma and UV Treatments. Applied Composite Materials 28 (2021) 71-89. (中科院三区;IF=2.181). 29. D. Quan et al. The curing behaviour and thermo-mechanical properties of core-shell rubber (CSR) modified epoxy nanocomposites. Polymers and Polymer Composites 27 (2019) 168-175 (中科院四区;IF=2.000). |