Dezembro 2024 vol. 11 num. 2 - X Simpósio Internacional de Inovação e Tecnologia

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INFLUENCE OF GRAPHENE ON POLYMERS HYDROPHOBICITY: A SYSTEMATIC REVIEW

INFLUENCE OF GRAPHENE ON POLYMERS HYDROPHOBICITY: A SYSTEMATIC REVIEW

Correia, Paulo Romano Cruz ; Leal, Débora ; Oliveira, Vinícius ; Kerche, Eduardo ; Polkowski, Rodrigo ;

Completo:

"This review reports advances in graphene/polymer composites, highlighting the potential of graphene as a nanofiller to improve the hydrophobicity of polymers. Following the PRISMA (Preferred Reporting Items for Systematic Reviews and Metaanalyses) protocol, the Scopus, Web of Science, and Lens databases were used to search for articles up to the year 2024. The search with the string “graphene AND polymer AND hydrophobic AND (contact AND angle)” resulted in 298 articles, of which 25 were considered relevant and selected for analysis. Processing techniques for the incorporation of graphene in the polymeric matrices were discussed. The articles reported that graphene-based composites improved properties such as hydrophobicity, antibacterial characteristics, and electrical and thermal conductivity, offering new industrial and technological applications."

Completo:

"This review reports advances in graphene/polymer composites, highlighting the potential of graphene as a nanofiller to improve the hydrophobicity of polymers. Following the PRISMA (Preferred Reporting Items for Systematic Reviews and Metaanalyses) protocol, the Scopus, Web of Science, and Lens databases were used to search for articles up to the year 2024. The search with the string “graphene AND polymer AND hydrophobic AND (contact AND angle)” resulted in 298 articles, of which 25 were considered relevant and selected for analysis. Processing techniques for the incorporation of graphene in the polymeric matrices were discussed. The articles reported that graphene-based composites improved properties such as hydrophobicity, antibacterial characteristics, and electrical and thermal conductivity, offering new industrial and technological applications."

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Palavras-chave: graphene, nanocomposite, hydrophobicity,

Palavras-chave: graphene, nanocomposite, hydrophobicity,

DOI: 10.5151/siintec2024-393470

Referências bibliográficas
  • [1] "1 ZHAO, Hongtao et al. Fast and facile graphene oxide grafting on hydrophobic polyamide fabric via
  • [2] electrophoretic deposition route. Journal of Materials Science, v. 53, p. 9504-9520, 2018.
  • [3] 2 JIANG, Yuting et al. Laser-etched stretchable graphene–polymer composite array for sensitive strain
  • [4] and viscosity sensors. Nano-Micro Letters, v. 11, p. 1-11, 2019.
  • [5] 3 MORADI, Rasoul et al. Preparation and characterization of polyvinylidene fluoride/graphene
  • [6] superhydrophobic fibrous films. Polymers, v. 7, n. 8, p. 1444-1463, 2015.
  • [7] 4 RAJENDER, Nutenki; SURESH, Kattimuttathu I.; SREEDHAR, Bojja. Comb‐like polymer‐graphene
  • [8] nanocomposites with improved adhesion properties via surface‐initiated atom transfer radical
  • [9] polymerization (SI‐ATRP). Journal of Applied Polymer Science, v. 135, n. 8, p. 45885, 2018.
  • [10] 5 UZOMA, Paul C. et al. Superhydrophobicity, conductivity and anticorrosion of robust siloxane-acrylic
  • [11] coatings modified with graphene nanosheets. Progress in Organic Coatings, v. 127, p. 239-251, 2019.
  • [12] 6 CASSIE, A. B. D.; BAXTER, SJToTFS. Wettability of porous surfaces. Transactions of the Faraday
  • [13] society, v. 40, p. 546-551, 1944.
  • [14] 7 WENZEL, Robert N. Resistance of solid surfaces to wetting by water. Industrial & engineering
  • [15] chemistry, v. 28, n. 8, p. 988-994, 1936.
  • [16] 8 ÁVILA, Antonio Ferreira et al. A nano-modified superhydrophobic membrane. Materials Research, v.
  • [17] 16, p. 609-613, 2013. 9 SHARIF, N. Akhavan et al. Nanocomposite coatings based on modified graphene oxide and
  • [18] polydimethylsiloxane: Characterization and thermal properties. Russian Journal of Applied
  • [19] Chemistry, v. 93, p. 1765-1773, 2020.
  • [20] 10 SHAMSEER, Larissa et al. Preferred reporting items for systematic review and meta-analysis
  • [21] protocols (PRISMA-P) 2015: elaboration and explanation. Bmj, v. 349, 2015.
  • [22] 11 WANG, Jingchao et al. Preparation of graphene/poly (vinyl alcohol) nanocomposites with enhanced
  • [23] mechanical properties and water resistance. Polymer International, v. 60, n. 5, p. 816-822, 2011.
  • [24] 12 KHAN, Zaheen U. et al. A review of graphene oxide, graphene buckypaper, and polymer/graphene
  • [25] composites: Properties and fabrication techniques. Journal of plastic film & sheeting, v. 32, n. 4, p.
  • [26] 336-379, 2016.
  • [27] 13 BAYAN, Rajarshi; KARAK, Niranjan. Bio-derived aliphatic hyperbranched polyurethane
  • [28] nanocomposites with inherent self healing tendency and surface hydrophobicity: Towards creating high
  • [29] performance smart materials. Composites Part A: Applied Science and Manufacturing, v. 110, p. 142-
  • [30] 153, 2018.
  • [31] 14 MUANCHAN, Paritat; KUROSE, Takashi; ITO, Hiroshi. Replication and thermal properties of onedimensional composite nanostructures with enhanced mechanical robustness. Journal of The
  • [32] Electrochemical Society, v. 166, n. 9, p. B3282, 2019.
  • [33] 15HUANG, Chen-Yang; CHIU, Chih-Wei. Facile fabrication of a stretchable and flexible nanofiber carbon
  • [34] film-sensing electrode by electrospinning and its application in smart clothing for ECG and EMG
  • [35] monitoring. ACS Applied Electronic Materials, v. 3, n. 2, p. 676-686, 2021.
  • [36] 16 ZHOU, Shuai et al. Property control of graphene aerogels by in situ growth of silicone polymer.
  • [37] Applied Surface Science, v. 439, p. 946-953, 2018.
  • [38] 17 LI, Ting‐Ting et al. Preparation of flexible, highly conductive polymer composite films based on double
  • [39] percolation structures and synergistic dispersion effect. Polymer Composites, v. 42, n. 10, p. 5159-
  • [40] 5167, 2021.
  • [41] 18 ZHANG, Fengyuan et al. Application of polyether amine intercalated graphene oxide as filler for
  • [42] enhancing hydrophobicity, thermal stability, mechanical and anti-corrosion properties of waterborne
  • [43] polyurethane. Diamond and Related Materials, v. 109, p. 108077, 2020.
  • [44] 19 LI, BangSen et al. Grafting photochromic spiropyran polymer brushes on graphene oxide surfaces via
  • [45] surface-initiated ring-opening metathesis polymerization. RSC advances, v. 14, n. 6, p. 3748-3756,
  • [46] 2024.
  • [47] 20 JEEVA, N.; THIRUNAVUKKARASU, K.; XAVIER, Joseph Raj. Multilayer Functional Polyurethane
  • [48] Nanocomposite Coating Containing Graphene Oxide and Silanized Zirconium Nitride for the Protection
  • [49] of Aluminum Alloy Structures in Aerospace Industries. Journal of Materials Engineering and
  • [50] Performance, p. 1-21, 2024.
  • [51] 21PARVEZ, Abu Naushad et al. Optimization of triboelectric energy harvesting from falling water droplet
  • [52] onto wrinkled polydimethylsiloxane-reduced graphene oxide nanocomposite surface. Composites Part
  • [53] B: Engineering, v. 174, p. 106923, 2019.
  • [54] 22 CHOI, Jong Han; LEE, Kwan Young; KIM, Sang Woo. Ultra-bendable and durable Graphene–
  • [55] Urethane composite/silver nanowire film for flexible transparent electrodes and electromagneticinterference shielding. Composites Part B: Engineering, v. 177, p. 107406, 2019.
  • [56] 23 ASENJO-SANZ, Isabel et al. Zwitterionic ring-opening polymerization for the facile, efficient and
  • [57] versatile grafting of functional polyethers onto graphene sheets. European Polymer Journal, v. 73, p.
  • [58] 413-422, 2015.
  • [59] 24 SHI, Chengyu et al. Highly‐durable hydrophobic and adhesive coatings fabricated from graphene‐
  • [60] grafted methacrylate copolymers. Journal of Applied Polymer Science, v. 139, n. 38, p. e52917, 2022.
  • [61] 25 WANG, Yu et al. Synthesis of photo‐crosslinked hybrid fluoropolymer and its application as releasing
  • [62] coating for silicone pressure‐sensitive adhesives. Journal of Applied Polymer Science, v. 137, n. 4,
  • [63] p. 48322, 2020.
  • [64] 26JAFARI, Abolfazal; MORTAHEB, Hamid Reza; GALLUCCI, Fausto. Performance of octadecylaminefunctionalized graphene oxide nanosheets in polydimethylsiloxane mixed matrix membranes for
  • [65] removal of toluene from water by pervaporation. Journal of Water Process Engineering, v. 45, p.
  • [66] 102497, 2022.
  • [67] 27 MO, Zhao-Hua et al. Superhydrophobic hybrid membranes by grafting arc-like macromolecular
  • [68] bridges on graphene sheets: synthesis, characterization and properties. Applied Surface Science, v.
  • [69] 440, p. 359-368, 2018.
  • [70] 28 ALAZZAM, Anas; ALAMOODI, Nahla. Microfluidic devices with patterned wettability using graphene
  • [71] oxide for continuous liquid–liquid two-phase separation. ACS Applied Nano Materials, v. 3, n. 4, p.
  • [72] 3471-3477, 2020"
Como citar:

Correia, Paulo Romano Cruz; Leal, Débora; Oliveira, Vinícius; Kerche, Eduardo; Polkowski, Rodrigo; "INFLUENCE OF GRAPHENE ON POLYMERS HYDROPHOBICITY: A SYSTEMATIC REVIEW", p. 1259-1266 . In: . São Paulo: Blucher, 2024.
ISSN 2357-7592, DOI 10.5151/siintec2024-393470

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