宋波
副教授
所属院部: 海洋学院
访问次数:
基本信息
  • 教师拼音名称:
    songbo
  • 入职时间:
    2015-07-20
  • 所在单位:
    海洋学院
  • 学历:
    研究生(博士后)
  • 性别:
  • 学位:
    工学博士学位
  • 在职信息:
    在职
  • 毕业院校:
    哈尔滨工业大学
  • 硕士生导师
学科:
材料科学与工程;
高分子化学与物理;
应用化学;
教育经历
  • 2009-3 — 2013-6
    哈尔滨工业大学
    化学工程与技术
    工学博士学位
工作经历
  • 2013-07 — 2015-07
    中国航天科工集团第六研究院
  • 2015-07-至今
    山东大学(威海)海洋学院
  • 2015-08 — 2018-07
    机电与信息工程学院
研究领域

环氧树脂基复合材料的结构设计与研发

功能性纳米复合材料的设计与制备

高性能纤维表面改性研究

海洋生物材料的开发与利用


科研成果
论文

1.  Boosting the interlaminar toughening capacity of PBO microfiber for carbon fiber laminates through the interface regulation of interleaving layer.  COMPOSITES PART B-ENGINEERING,  299,  112404,

2.  Polymorphic Transformation and Magnetic Properties of Rapidly Solidified Fe26.7Co26.7Ni26.7Si8.9B11.0 High-Entropy Alloys.  MATERIALS,  12,  12040590,

3.  Structural, electronic, optical and lattice dynamic properties of the different WO3 phases: First-principle calculation.  Vacuum,  164,  411-420,

4.  Influence of the hybrid ratio and stacking sequence on mechanical and damping properties of hybrid composites.  POLYMER COMPOSITES,  40,  2368-2380,

5.  A New Filler for Epoxy Resin: Study on the Properties of Graphite Carbon Nitride (g-C3N4) Reinforced Epoxy Resin Composites.  POLYMERS,  12,  12010076,

6.  Carbon nitride nanoplatelet photocatalysts heterostructured with B-doped carbon nanodots for enhanced photodegradation of organic pollutants.  JOURNAL OF COLLOID AND INTERFACE SCIENCE,  559,  124-133,

7.  Significant improved interfacial properties of PBO fibers composites by in-situ constructing rigid dendritic polymers on fiber surface.  APPLIED SURFACE SCIENCE,  512,  145719,

8.  Significantly Strengthening Epoxy by Incorporating Carbon Nanotubes/Graphitic Carbon Nitride Hybrid Nanofillers.  MACROMOLECULAR MATERIALS AND ENGINEERING,  305,  2000231,

9.  Layer-by-layer constructing interface with rigid-flexible transition structure for improving interfacial adhesion of PBO fiber composites.  Composites Communications,  22,  100466,

10.  Grafting of CNTs onto the surface of PBO fibers at high-density for enhancing interfacial adhesion, mechanical properties and stability of composites.  Journal of Colloid and Interface Science,  598,  113-125,

11.  Enhancing interfacial adhesion and mechanical performance of PBO fibers composites through mussel-inspired molecular regulation of interphase structure.  POLYMER COMPOSITES,  43,  454-466,

12.  Poly(p-phenylene benzobisoxazole) Fiber/Epoxy Composites Reinforced with Carbon Nanotubes and Graphene Oxide for Enhanced Interfacial Adhesion and Mechanical Strength.  ACS APPLIED NANO MATERIALS,  4,  12158-12169,

13.  A high-efficient and ultra-strong interfacial solar evaporator based on carbon-fiber fabric for seawater and wastewater purification.  DESALINATION,  527,  115586,

14.  FDM 3D-printed volcanic-shaped structure for ultrafast solar-driven interfacial evaporation and efficient energy utilization.  DESALINATION,  548,  116275,

15.  Pyramid-shaped solar evaporator with high-efficient interfacial evaporation and salt harvesting capability.  JOURNAL OF CLEANER PRODUCTION,  434,  139956,

16.  In-situ constructing cellulose/PVA hydrogel with confinement capillarity for efficient solar interfacial evaporation.  DESALINATION,  565,  116855,

17.  PVA/cellulose hydrogel with asymmetric distribution of MoS2 for highly efficient solar-driven interfacial evaporation and electricity generation.  DESALINATION,  588,  117934,

18.  Spider-web-structured CNTs/CuS coating-based flexible pressure sensor with extreme self-heating and anti-freezing ability as a safeguard for winter sports.  JOURNAL OF MATERIALS CHEMISTRY C,  12,  16431-16442,

19.  Three birds with one stone: Constructing Janus multilayer carbon fabric to boost solar-driven interfacial evaporation, electrical power generation and inhibit VOCs volatilization.  CHEMICAL ENGINEERING JOURNAL,  500,  156827,

20.  Synthesis, Properties, and Applications of Low-Dimensional Carbon-Related Nanomaterials.  JOURNAL OF NANOMATERIALS,  2010,  685081,

21.  Influence of plasma treatment time on plasma induced vapor phase grafting modification of PBO fiber surface.  APPLIED SURFACE SCIENCE,  258,  5505-5510,

22.  Surface modification of PBO fiber through oxygen plasma induced vapor phase grafting of acrylic acid.  MATERIALS LETTERS,  83,  118-120,

23.  Improvement of interfacial property between PBO fibers and epoxy resin by surface grafting of polyhedral oligomeric silsesquioxanes (POSS).  APPLIED SURFACE SCIENCE,  258,  10154-10159,

24.  Preparation and characterization of (POSS/TiO2)n multi-coatings based on PBO fiber surface for improvement of UV resistance.  FIBERS AND POLYMERS,  14,  375-381,

25.  Biomimetic Construction of PBO Fiber Hierarchical Reinforcement with Simultaneously Enhanced Interfacial Properties and Atomic Oxygen Erosion Resistance for Advanced Composites.  FIBERS AND POLYMERS, 

26.  Two-step hydrothermally synthesized carbon nanodots/WO3 photocatalysts with enhanced photocatalytic performance.  DALTON TRANSACTIONS,  46,  15769-15777,

27.  Preliminarily optimizing glass-forming compositions in metal-metal type ternary alloy systems with a large-sized solvent element.  AIP Advances,  8,  105119,

28.  Graphitic carbon nitride (g-C3N4) interfacially strengthened carbon fiber epoxy composites.  Composites Science and Technology,  167,  515-521,

29.  Effect of Dimensions and Agglomerations of Carbon Nanotubes on Synchronous Enhancement of Mechanical and Damping Properties of Epoxy Nanocomposites.  NANOMATERIALS,  8,  996,

30.  Interfacially reinforced carbon fiber/epoxy composite laminates via in-situ synthesized graphitic carbon nitride (g-C3N4).  COMPOSITES PART B-ENGINEERING,  158,  259-268,

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