APPLICATION PROGRESS OF CARBON-BASED FUNCTIONAL MATERIALS IN THE MARINE FIELD
Keywords:
Marine science and technology, Carbon-based materials, GraphenAbstract
"Marine Strategy" is an important national development strategy of China. Marine resource development and environmental protection, maritime transportation, seaport and coastal defense construction, marine engineering equipment, and marine exploration equipment all require a large number of new functional materials. Carbon-based materials have shown good application prospects in many scientific and engineering fields. This article systematically reviews the application progress of carbon-based functional materials in the field of marine science, focusing on the applications in environmental emergency materials, anti-corrosion coatings, structural materials, seawater desalination and other fields. It also reviews the emerging applications of carbon-based functional materials in marine energy storage and other fields. Directional applications are prospected.References
[1] Yun Yinsheng, Huang Xiang, Dong Lihua. Marine engineering materials science. Beijing: Science Publishing, 2008.
[2] Inagaki M, Kang FY. Carbon Materials and Engineering-from Fundamentals to Applications. Tsinghua University Press, 2006.
[3] Hossain MK, Chowdhury MMR, Imran KA. Effect of low velocity impact responses on durability of conventional and nanophased CFRP composites exposed to seawater. Polymer Degradation and Stability, 2014, 99: 180-189.
[4] Valenza A, Fiore V, Di Bella G. Effect of UD carbon on the specific mechanical properties of glass mat composites for marine applications. Journal of Composite Materials, 2010, 44 (11): 1351.
[5] Yu Liwei, Cao Weiyu. Application of carbon fiber composite materials in the ocean. New Chemical Materials, 2016, 44(8): 4-6.
[6] Tang Hongyan, Wang Jihui, Xu Pengyao. Current status and progress of foreign application of composite materials on naval ships. Ships, 2006, 19(2): 6-11.
[7] Sun XS, Chen Y, Tan VBC. Homogenization and stress analysis of multilayered composite offshore production risers. Journal of Applied Mechanics, 2014, 81(3): 1-11.
[8] Yi Ming. Application of carbon fiber composite materials in deep sea oil and gas development. New Materials Industry, 2013, 11: 31-36.
[9] Luo Yongkang, Li Wei. Application of carbon fiber composite materials in wind turbine blades. Power Grid and Clean Energy, 2008, 24(5): 53-57.
[10] Annunciado T R , Sydenstricker T H D, Amico S C. Experi-mental investigation of various vegetable fibers as sorbent mate-rials for oil spills. Marine Pollution Bulletin , 2005 , 50: 1340-1346.
[11] Radeti' c M M, Joci' c D M , Iovanti' c P M. Recycled wool-based nonwoven material as an oil sorbent. Environmental Science and Technology, 2003, 37: 1008-1012.
[12] Xu M Y, Wang G, Zeng Z X. Diverse wettability of su-peroleophilicity and superoleophobicity for oil spill cleanup and recycling. Applied Surface Science , 2017 , 426: 1158-1166.
[13] Singh E , Chen Z P , Housmand F. Superhydrophobic Graphene Foams. Small, 2013, 9( 1) : 75-80.
[14] Bi H C, Xie X, Yin K B. Spongy graphene as a highly efficient and recyclable sorbent for oils and organic solvents. Advanced Functional Materials , 2012 , 22 (21 ) : 4421-4425.
[15] Niu Z Q, Chen J, Hng H H. A leavening strategy to pre-pare reduced graphene oxide foams. Advanced Materials, 2012, 24(30) : 4144-4150.
[16] Dong X C, Chen J, Ma Y W. Superhydrophobic and su-peroleophilic hybrid foam of graphene and carbon nanotube for selective removal of oils or organic solvents from the surface of water. Chemical Communications , 2012 , 48: 10660-10662.
[17] Zhao Y, Hu C G, Hu Y. A versatile, ultralight, nitro-gen-doped graphene framework. Angew andte Chemie-Inter-national Edition, 2012, 51(45) : 11371-11375.
[18] Sun HY, Xu Z, Gao C. Multifunctional, ultra-flyweight, synergistically assembled carbon aerogels. Advanced Materials, 2013, 25(18): 2554-2560.
[19] Hu H, Zhao ZB, Gogotsi Y. Compressible carbon nano-tube-graphene hybrid aerogels with superhydrophobicity and su-peroleophilicity for oil sorption. Environmental Science& Technology Letters, 2014, 1(3): 214-220.
[20] Ge J, Shi LA, Wang YC. Joule-heated graphene-wrapped sponge enables fast clean-up of viscos crude-oil spill. Nature Nanotechnology, 2017, 12: 434-440.
[21] Li Zengxin, Wang Tong, Meng Yun. Application of expanded graphite in environmental pollution control. Journal of Environmental Engineering, 2007, 2(1): 69-72.
[22] Wang Hongxi, Wang Hongxia, Xue Li. Research on the oil absorption performance of expanded graphite. Carbon Technology, 2004, 5(23): 21-23.
[23] Shen Qingfeng, Zhao Jinglian, Lu Xiaowen. Preparation of expanded graphite adsorbent and study on its oil absorption performance. Industrial Water Treatment, 2010, 30(8): 57-60.
[24] Elimelech M, Phillip WA. The Future of seawater desalination: Energy, technology, and the environment. Science, 2011, 333(6043): 712-717.
[25] Werber JR, Osuji CO, Elimelech M. Materials for next-generation desalination and water purification membranes. Nature Reviews Materials, 2016, 1(5): 16018.
[26] Subramani A, Jacangelo JG. Emerging desalination technologies for water treatment: A critical review. Water Research, 2015, 75: 164-187.
[27] Corry B. Designing carbon nanotube membranes for efficient water desalination. Journal of Physical Chemistry B, 2008, 112(5) : 1427-1434.
[28] Das R, Ali ME, Abd Hamid SB. Carbon nanotube mem-branes for water purification : A bright future in water desalina-tion. 2013, 336: 97-109.
[29] Yang Q, Su Y, Chi C. Ultrathin graphene-based mem-brane with precise molecular sieving and ultrafast solvent perme-ation. Nature Materials, 2017, 16: 1198-1202.
[30] Su Y , Kravets V G , Wong S L. Impermeable barrier films and protective coatings based on reduced graphene oxide. Nature Communications, 2014, 5: 4843.
[31] Abraham J, Vasu K S, Williams C D. Tunable sieving of ions using graphene oxide membranes. Nature Nanotechnology, 2017, 12: 546-550.
[32] Chen L, Shi GS, Shen J. Ion sieving in graphene oxide membranes via cationic control of interlayer spacing. Science, 2017, 550: 380.
[33] Liu Guojie. Preliminary progress in the industrialization research and development of graphene heavy-duty anti-corrosion coating. China Coatings, 2016, 31: 6-15.