论文

【复合材料方向】

(1)      Establishment of multi-scale interface in interlayer-toughened CFRP composites by self-assembled PA-MWNTs-EP.
Dawei Liu, Gang Li, Bo Li, Xiaoping Yang
Composite Science and Technology, 2016，130: 53-622.

(2)      In-situ toughened CFRP composites by shear-calender orientation and fiber-bundle filtration of PA microparticles at prepreg interlayer.
Dawei Liu, Bo Li, Gang Li, Yihao Luan, Hui Ling, Xiaoping Yang
Composites: Part A, 2016, 84: 165-174.

(4)      A kind of liquid-like MWCNT reinforcements for T1000 carbon fiber filament winding composites.

           Zhang QJ, Li XC, Liang SB, Zhao XF, Sui G, Yang XP

           Composites Science & Technology, 2016, 131: 89-97.

(6)      Enhancing Biological Properties of Carbon Nanofibers by Controlling Crystallization of Incorporated Bioactive Glass via Silicon Content.

Dan Cheng, Rongrong Xie, Le Jin, Man Cao, Xiaolong Jia, Qing Cai and Xiaoping Yang

RSC Adv., 2016, 6, 53958-53966.

(7)      Regulating micro-structure and biomineralization of electrospsun PVP-based hybridized carbon nanofibers containing bioglass nanoparticles via aging time.

Dan Cheng, Rongrong Xie, Tianhong Tang, Xiaolong Jia*, Qing Cai and Xiaoping Yang

RSC Adv., 2016, 6, 3870-3881.

(8)      Thermal-based regulation on biomineralization and biological properties of bioglass nanoparticles decorated PAN-based carbon nanofibers.

Dan Cheng, Zhiwei Ren, Lijuan Guo, Cuihua Zhang, Xiaolong Jia*, Qing Cai and Xiaoping Yang

RSC Adv., 2016, 6, 428-438.

(9)      Direct Fabrication of SiO2-PMMA Nanosphere Composed Nanofibers via Electrospinning.

Ran Zhang, Tinghua Shang, Guang Yang, Xiaolong Jia, Qing Cai, Xiaoping Yang

Colloids and Surfaces B: Biointerfaces, 2016, 144: 238-249.

(10)   Effectively Exerting the Reinforcement of Dopamine Reduced Graphene Oxide on Epoxy-Based Composites via Strengthened Interfacial Bonding.

Wenbin Li, Tinghua Shang, Wengang Yang, Huichuan Yang, Song Lin, Xiaolong Jia, Qing Cai, and Xiaoping Yang

ACS Applied Material & Interfaces. 2016, 8 (20):13037–13050.

(11)   Preparation and characterization of the modulus intermediate layer in carbon fiber/epoxy composites by depositing sepiolites.

         Yang Q, Zhang QJ, Chen X, Deng X, Qi SL, Sui G, He ZW, Lan FT, Wu DZ, Yang XP

        Journal of Applied Polymer Science, 2016 (37).

(12)   Effect of different amino functionalized carbon nanotubes on curing behavior and mechanical properties of carbon fiber/epoxy composites.

         Wu JQ, Guo J, Zhang QJ, Gao L, Li H, Deng HY, Jiang WG, Sui G, Yang XP

         Polymer Composites, 2016.

(13)   Effects of the amine/epoxy stoichiometry on the curing behavior and glass transition temperature of MWCNTs-NH2/epoxy nanocomposites.

          Gao L, Zhang QJ, Guo J, Li H, Wu JQ, Sui G, Yang XP

          Thermochimica Acta, 2016, 639: 98-107.

(14)   环氧化合物表面上浆处理的MWCNTs对环氧树脂复合材料性能的影响.

   赵新福, 张清杰, 郭健, 高亮, 隋刚, 杨小平

   复合材料学报, 2016.

(15)   胺/环氧当量比对MWCNTs-NH2/环氧树脂复合材料性能的影响.

   唐峰, 张清杰, 高亮, 吴剑桥, 隋刚, 杨小平

   玻璃钢/复合材料, 2016, 5: 85-90.

(16)   MWCNTs-NH2/环氧树脂纳米复合材料压缩性能影响机理.

   唐峰, 张清杰, 高亮, 吴剑桥, 隋刚, 杨小平

   北京化工大学学报自然科学版, 2016, 43, 2: 48-52.

(17)   环氧树脂高低温弹性模量的分子模拟和实验研究.

   李浩, 张清杰, 高亮, 张文卿, 隋刚, 杨小平

   玻璃钢/复合材料, 2016, 8: 33-37.

(18)   高柔性低面密度预浸料的制备与性能研究.

   刘大伟, 李波, 李刚, 杨小平

   宇航材料工艺，46(4), 40-42.

【能源材料方向】

(1)    Carbon nanofibers-based materials as anode materials for lithium-ion-batteries.

        Yu YH, Liu Y, Yang XP

        Alkali-Ion batteries/InTech, 2016.7 (ISBN 978-953-51-2395-8).

(2)    Eco-friendly fabricated porous carbon nanofibers decorated with nanosized SnO_x as high-performance lithium-ion battery anodes.

        Liu Y, Yan XD, Yu YH, Yang XP

       ACS Sunstainable Chemistry & Engineering, 2016, 4(6): 2951-2959.

(3)    Phosphorus groups assisted growth of vertically oriented polyaniline nanothorns on N/P co-doped carbon nanofibers for high-performance supercapacitors.

        Fan XR, Yan XD,Yu YH, Lan JL, Yang XP

        Electrochimica Acta, 2016, 216: 355-363.

(5)    Studies on soy protein isolate/polyvinyl alcohol hybrid nanofiber membranes as multi-functional eco-friendly filtration materials.

        Fang Q, Zhu M, Yu SR, Sui G, Yang XP

        Materials Science and Engineering: B, 2016, 214: 1-10.

(6)    Degradable cellulose acetate/poly-L-lactic acid/halloysite nanotube composite nanofiber membranes with outstanding performance for gel polymer electrolytes.

        Zhu M, Lan JL, Tan CY, Sui G, Yang XP

        Journal of Materials Chemistry A, 2016, 4, 31: 12136-12143.

(7)    High performance and biodegradable skeleton material based on soy protein isolate for gel polymer electrolyte.

        Zhu M, Tan C, Fang Q, Sui G, Yang XP

        ACS Sustainable Chemistry & Engineering, 2016, 4, 9: 4498-4505.

(8)    Viable Synthesis of Highly Compressible, Ultra-Light Graphene-Carbon Nanotube Composite Aerogel without Additional Reductant and its Applications for Strain-Sensitivity.

        Gao L#, Wang F#, Zhan WW, Wang Y, Sui G, Yang XP

        Chemical Communications, 2016, DOI: 10.1039/C6CC07450B.

(9)    Polyhedral oligomeric silsesquioxane modified carbon nanotube hybrid material with a bump structure via polydopamine transition layer.

         Gao L, Zhang QJ, Zhu M, Zhang X, Sui G, Yang XP

         Materials Letters, 2016, 183:207-210.

【生物材料方向】

(1)    Flexible fiber-reinforced composites with improved interfacial adhesion  by mussel-inspired polydopamine and poly(methyl methacrylate) coating.

        Yi Mi, Sun HY, Zhang HC, Deng XK, Cai Q, Yang XP

        Mat Sci Eng C, 2016, 58: 742-749.

(2)    Improved performances of Bis-GMA/TEGDMA composites by net-like structured SiO2 nanofiber fillers.

        Wang XY, Cai Q, Zhang XH, Liu L, Wei Y, Xu MM, Yang XP, Ma Q, Deng XL

        Mat Sci Eng C, 2016, 59: 464-470.

(3)    Improving interfacial adhesion with epoxy matrix using hybridized carbon nanofibers containing calcium phosphate nanoparticles.

        Gao XK, Lan JL, Jia XL, Cai Q, Yang XP

        Mat Sci Eng C, 2016, 61: 174-179.

(4)    Thermal-based regulation on biomineralization and biological properties of bioglass nanoparticles decorated PAN-based carbon nanofibers.

        Cheng D, Ren ZW, Guo LJ, Zhang CH, Jia XL, Cai Q

        RSC Adv, 2016, 6: 428-438.

(5)    Regulating micro-structure and biomineralization of electropsun PVP-based hybridized carbon nanofibers containing bioglass nanoparticles via aging time.

        Cheng D, Xie RR, Tang TH, Jia XL, Cai Q, Yang XP

        RSC Adv, 2016, 6: 3870-3881.

(6)    Enhancing the biological properties of carbon nanofibers by controlling the crystallization of incorporated bioactive glass via silicon content.

         Cheng D, Xie RR, Jin L, Cao M, Jia XL, Cai Q, Yang XP

RSC Adv, 2016, 6: 53958-53966.

(7)    Influence of Cement Thickness on Adhesive Properties of CAD/CAM Fabricated One-piece Fiber Post-and-core: Micro Push-out and Finite Element Analysis Study.

        Su J, Cai Q, Huang ZX, Zhang HC, Deng XL, Yang XP

        Dentistry(OMICS Biomedical Journals)-open access, 2016, 6(6): 382, 7 pages.

(8)    Direct Fabrication of SiO2-PMMA Nanosphere Composed Nanofibers via Electrospinning.

        Zhang R, Jia XL, Yang G, Cai Q, Yang XP

        Colloid Surf B Biointerfaces, 2016, 144: 238–249.

(9)    Regulating proliferation and differentiation of osteoblasts on poly(l-lactide)/gelatin composite nanofibers via timed biomineralization.

         Zhang CJ, Cao M, Lan JL, Wei PF, Cai Q, Yang XP

         J Biomed Mater Res A, 2016, 104(8): 1968-1980.

(10)   Effectively exerting the reinforcement of dopamine reduced graphene oxide on epoxy-based composites via strengthened interfacial bonding.

         Li WB, Shang TH, Yang WG, Lin S, Jia XL, Cai Q, Yang XP

         ACS Appl Mater Interfaces, 2016, 8: 13037-13050.

(11)   Dual functional polylactide-hydroxyapatite nanocomposites for bone regeneration with nano-silver being loaded via reductive polydopamine.

         Zhu SQ, Sun HY, Geng HG, Liu DP, Zhang X, Cai Q, Yang XP

          RSC Adv, 2016, 6: 91349 – 91360.

(12)   Composite resin reinforced with silver nanoparticles - laden hydroxyapatite nanowires for dental application.

Ai M, Du ZY, Zhu SQ, Geng HJ, Zhang X, Cai Q, Yang XP

Dent Mater, Published online.

(13)   Photoluminescent biodegradable polyphosphazenes for long-term in vivo tracking for tissue engineering application. Zhaohui Huang, Lika Yang, Xuehui.

Zhang, Bingyuan Ruan, Xiaoqing Hu,  Deng XL, Cai Q, Yang XP

         Macromolecules, 2016, 49(22): 8508-8519.

(14)   Cell studies of hybridized carbon nanofibers containing bioactive glass nanoparticles using bone mesenchymal stromal cells.

          Zhang XR, Hu XQ, Jia XL, Yang LK,Meng QY, Shi YY, Zhang ZZ, Cai Q, Ao YF, Yang XP.

          Sci Report, 2016, 6: 38685 | DOI: 10.1038/srep38685.

(16)   Gold nanoparticle-conjugated heterogeneous polymer brush-wrapped cellulose nanocrystals by combining different controllable polymerization techniques for theranostic applications.

Hu H, Hou XJ, Wang XC, Nie JJ, Cai Q, Xu FJ.  

Polym Chem, 2016, 7: 3107-3116.