Use of Nano composites in industries
DOI:
10.47709/brilliance.v2i3.1691Keywords:
Application of Nano Composites, aerospace, Environmental friendlyDimension Badge Record
Abstract
High performance materials called Nano composites have unique features. Engineering plastics and elastomers are where Nano composites are most in demand, with an anticipated 25% annual growth rate. Their potential is so great that they are useful in many applications, from packaging to biomedical ones. The many forms of matrix Nano composites are covered in this review, with an emphasis on the need for these materials, their methods of manufacturing, and some recent findings regarding their structure, characteristics, and possible uses. The necessity for such materials in the future as well as other intriguing applications are projected. Applications of nano composites offer new technical and commercial potential for numerous sectors of the aerospace, automotive, electronics, and biotechnology industries because to their environmental friendliness.
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References
Dalton AB, Coolins S, Munoz E, et al. Super-tough carbon-nanotube fibres: these extraordinary composite fibres can be woven into electronic textiles. Nature 2003; 423 (6941): 703-703.
Roy R, Roy RA, Roy DM. Alternative perspectives on “quasi-crystallinity”: non-uniformity and nanocomposites. Materials Letters 1986; 4 (8-9): 323-328.
Ounaies Z, Park C, Wise KE, et al. Electrical properties of single wall carbon nanotube reinforced polyimide composites. Composites Science and Technology 2003; 63 (11): 1637-1646.
Schmidt D, Shah D, Giannelis EP. New advances in polymer/layered silicate nanocomposites. Current Opinion in Solid State & Materials Science 2002; 6 (3): 205-212.
Gleiter H. Materials with ultrafine microstructures: Retrospectives and perspectives. Nanostructured Materials 1992; 1 (1): 1-19.
Iijima S. Helical microtubes of graphitic carbon. Nature 1991; 354 (6348): 56-58.
Braun T, Schubert A, Sindelys Z, Nanoscience and nanotechnology on the balance. Scientometrics 1997; 38 (2): 321-325.
Kamigaito O, What can be improved by nanometer composites? Journal of Japan Society of Powder Metalurgy 1991; 38: 315-321.
Biercuk MJ, Llaguno MC, Radosvljevicm H, Carbon nanotube composites for thermal management. Appied Physics Letters 2002; 80 (15): 2767-2769
Weisenberger MC, Grulke EA, Jacques D, et al. Enhanced mechanical properties of polyacrylonitrile: multiwall carbon nanotube composite fibers. Journal of Nanoscience and Nanotechnology 2003; 3 (6) 535-539.
Choa YH, Yang JK, Kim BH, et al. Preparation and characterization of metal: ceramic nanoporous nanocomposite powders. Journal of Magnetism and Magnetic Materials 2003; 266 (1-2) 12-19.
Wypych F, Seefeld N, Denicolo I. Preparation of nanocomposites based on the encapsulation of conducting polymers into 2H-MoS2 and 1T-TiS2. Quimica Nova. 1997;20 (4):356-360.
Aruna ST, Rajam KS. Synthesis, characterisation and properties of Ni/PSZ and Ni/YSZ nanocomposites. Scripta Materialia 2003;48 (5): 507-512.
Giannelis EP. Polymer layered silicate nanocomposites. Advanced Materials 1996; 8 (1): 29-35.
Sternitzke M, Review: Structural ceramic nanocomposites. Journal of European Ceramic Society 1997; 17 (9): 1061-1082.
Peigney A, Laurent CH, Flahaut E, et al. Carbon nanotubes in novel ceramic matrix nanocomposites. Ceramic International 2000;26 (6): 677-683.
Alexandre M, Dubois P. Polymer-layered silicate nanocomposites: Preparation, properties and uses of a new class of materials. Materials Science & Engineering 2000; 28 (1-2): 1-63.
Gangopadhyay R, Amitabha D, Conducting polymer nanocomposites: A brief overview. Chemistry of Materials 2000; 12 (7): 608-622.
Pandey JK, Reddy KR, Kumar AP, et al. An overview on the degradability of polymer nanocomposites. Polymer Degradation and Stability. 2005 88 (2) 234-250.
Thostenson ET, Li C, Chou TW. Nanocomposites in context. Composites Science and Technology 2005; 65 (3-4): 491-516.
Jordan J, Jacob KI, Tannenbaum R, et al. Experimental trends in polymer nanocomposites: a review. Materials Science and Engineering: A. 2005; 393 (1-2): 1-11.
Choi SM, Awaji H, Nanocomposites: A new material design concept. Science and Technology of Advanced Materials 2005; 6 (1): 2-10.
Xie XL, Mai YW, Zhou XP. Dispersion and alignment of carbon nanotubes in polymer matrix: a review. Materials Science and Engineering: R. 2005; 49 (4): 89-112.
Ray SS, Bousmina M. Biodegradable polymers and their layered silicate nanocomposites: in greening the 21st century materials world. Progress in Matererials Science 2005; 50 (8): 962-1079.
Pandey JK, Kumar AP, Misra M, et al, Recent advances in biodegradable nanocomposites. Journal of Nanoscience and Nanotechnology 2005; 5 (4): 497-526.
Awaji H, Choi SM, Yagi E, Mechanisms of toughening and strengthening in cermaic-based nanocomposites. Mechanics of Materials 2002; 34 (7): 411-422.
Niihara K, New design concept of structural ceramics-ceramic nanocomposite. Journal of the Ceramic Society of Japan 1991; 99 (6): 974-982.
Al?Bahrani, M., Majdi, H. S., Abed, A. M., & Cree, A. (2022). An innovated method to monitor the health condition of the thermoelectric cooling system using nanocomposite?based CNTs. International Journal of Energy Research, 46(6), 7519-7528.
Chang JH, An YU. Nanocomposites of polyurethane with various organoclays: thermo mechanical properties, morphology, and gas permeability. Journal of European Ceramic Society 2002; 40 (7): 670-677.
Zavyalov SA, Pivkina AN, Schoonman J. Formation and characterization of metal-polymer nanostructured composites. Solid State Ionics 2002; 147 (3-4): 415-419.
Thompson CM., Herring HM, Gates TS, et al. Preparation and characterization of metal oxide/polyimide nanocomposites. Composites Science and Technology 2003 63 (11): 1591-1598.
Liu TX, Phang IY, Shen L, et al. Morphology and mechanical properties of multiwalled carbon nanotubes reinforced nylon-6 composites. Macromolecules. 2004; 37 (19): 7214-7222.
Shah MA, Sheikh NA, Najar KA, et al. Influence of boron doping on mechanical and tribological properties in multilayer CVD diamond coating system. Bulletin of Material science 2016, 39:1753-1761.
Ogawa M, Kuroda K, Preparation of inorganic composites through intercalation of organoammoniumions into layered silicates. Bulletin of the Chemical Society of Japan 1997; 70 (11): 2593-2618.
Kojima Y, Usuki A, Kawasumi M, et al. Mechanical properties of nylon-6-clay hybrid. Journal of Materials Research 1993; 8 (5): 1185-1189.
Stearns LC, Zhao J, Martin P, Harmer Processing and microstructure development in Al2O3-SiC ‘nanocomposites’. Journal of European Ceramic Society 1992; 10 (3): 473-477.
Al-Bahrani, M. (2019). The Manufacture and Testing of Self-Sensing CNTs Nanocomposites for Damage Detecting Applications (Doctoral dissertation, University of Plymouth).
Riedel R, Strecker K, Petzow G, In situ polysilane-derived silicon-carbide particulates dispersed in silicon nitride composite. Journal of the American Ceramic Society 1989; 72(11): 2071-2077.
Riedel R, Seher M, Becker G, Sintering of amorphous polymer-derived Si, N and C containing composite powders. Journal of European Ceramic Society 1989; 5 (2): 113-122.
Din SH, Shah MA, Sheikh NA, Effect of CVD-diamond on the Tribological and Mechanical Performance of Titanium Alloy (Ti6Al4V). Tribology in Industry 2016; 38: 530-542.
Vorotilov KA., Yanovskaya MI, Turevskaya EP, et al, Sol-gel derived ferroelectric thin films: Avenues for control of microstructural and electric properties. Journal of Sol-Gel Science and Technology 1999; 16 (2): 109-118.
Hench LL, West JK. The sol-gel process. Chemical Review 1990; 90 (1): 33-72.
Ennas G, Mei A, Musinu A, et al. Sol-gel preparation and characterization of Ni-SiO2 nanocomposites. Journal of Non-Crystalline Solids 1998; 232-234: 587-593.
Al-Abboodi, H., Fan, H., Mhmood, I. A., & Al-Bahrani, M. (2022). The dry sliding wear rate of a Fe-based amorphous coating prepared on mild steel by HVOF thermal spraying. Journal of Materials Research and Technology, 18, 1682-1691.
Viart N, Richard-Plouet M, Muller D, et al. Synthesis and characterizationof Co/ZnO nanocomposites: Towards new perspectives offered by metal/piezoelectric composite materials. Thin Solid Films 2003; 437(1-2): 1-9.
Kundu TK, Mukherjee M, Chakravorty D, et al. Growth of nano-alpha-Fe2O3 in a titania matrix by the sol gel route. Journal of Matererials Science 1998; 33 (7): 1759-1763.
Baiju K, Sibu CP, Rajesh K, et al. An aqueous sol-gel route to synthesize nanosized lanthana doped titania having an increased anatase phase stability for photocatalytic application. Materials Chemistry and Physics 2005; 90 (1): 123-127.
Ananthakumar S, Prabhakaran AK, Hareesh US, et al. Gel casting process For Al2O3-SiC nanocompositees and its creep characteristics. Materials Chemistry and Physics 2004; 85 (1): 151-157.
Sivakumar S, Sibu CP, Mukundan P, et al. Nanoporous titania-alumina mixed oxides: an alkoxide free sol-gel synthesis. Materials Letters 2004; 58 (21): 2664-2669.
Warrier KGK, Anilkumar GM. Densification of mullite-SiC nanocomposite sol-gel precursors by pressureless sintering. Materials Chemistry and Physics 2001; 67 (1-3): 263-266.
Wunderlich W, Padmaja P, Warrier KGK, TEM characterization of sol-gel-processed alumina–silica and alumina–titania nano-hybrid oxide catalysts. Journal of European Ceramic Society 2004; 24 (2): 313-317.
Al?Bahrani, M., Graham?Jones, J., Gombos, Z., Al?Ani, A., & Cree, A. (2020). High?efficient multifunctional self?heating nanocomposite?based MWCNTs for energy applications. International Journal of Energy Research, 44(2), 1113-1124.
Yu MF, Lourie O, Moloni K, et al. Strength and breaking mechanism of multiwalled carbon nanotubes under tensile load. Science 2000; 287: 637-640.
Novoselov KS, et al. Two-dimensional gas of massless Dirac fermions in graphene. Nature 2005;438: 197-200.
Al-Bahrani, M., & Cree, A. (2021). Micro-scale damage sensing in self-sensing nanocomposite material based CNTs. Composites Part B: Engineering, 205, 108479.
Hirata M, Gotou T, Horiuchi S, et al. Thin-film particles of graphite oxide 1: High-yield synthesis and flexibility of the particles. Carbon 2004; 42: 2929–2937.
Novoselov KS. et al. Electric field effect in atomically thin carbon films. Science 2004; 306: 666–-669.
Zhang Y, Small JP, Amori ME,et al. Electric field modulation of galvanomagnetic properties of mesoscopic graphite. Phys. Rev. Lett 2005; 94: 176803.
Berger C, et al. Ultrathin epitaxial graphite: Two-dimensional electron gas properties and a route toward graphene-based nanoelectronics. J. Phys. Chem. B 2004; 108: 19912-19916.
Stankovich S, et al. Stable aqueous dispersions of graphitic nanoplatelets via the reduction of exfoliated graphite oxide in the presence of poly(sodium 4- styrenesulfonate). J. Mater. Chem 2006;. 16: 155-158.
Stauffer D, Aharnoy A. Introduction to Percolation Theory (Taylor & Francis, London, 1991).
Ounaies Z, Park C, Wise KE, et al. Electrical properties of single wall carbon nanotube reinforced polyimide composites. Compos. Sci. Techno 2003l; 63: 1637-1646.
Chung DDL. Electrical applications of carbon materials. J. Mater. Sci.2004; 39: 2645–-2661.
Al-Bahrani, M., Aljuboury, M., & Cree, A. (2018). Damage sensing and mechanical properties of laminate composite based MWCNTs under anticlastic test. Materials Research Express, 6(3), 035704.
He H, Klinowski J, Forster M,et al. A new structural model for graphite oxide. Chem. Phys. Lett.1998; 287: 53-56.
Zhang Y, Tan Y., Stormer HL,et al. Experimental observation of the quantum Hall effect and Berry’s phase in graphene. Nature 2005; 438: 201–-204 (2005).
Lerf A, He H, Forster M,et al. Structure of graphite oxide revisited. J. Phys. Chem. B 1998;102: 4477-4482.
Hirata M, Gotou T, Ohba M. Thin-film particles of graphite oxide 2: Preliminary studies for internal micro fabrication of single particle and carbonaceous electronic circuits. Carbon 2005; 43: 503-510.
Kovtyukhova NI, et al. Layer-by-layer assembly of ultrathin composite films from micron-sized graphite oxide sheets and polycations. Chem. Mater. 11 771-778 (1999).
Kotov NA, Dekany I, Fendler JH. Ultrathin graphite oxide-polyelectrolyte composites prepared by self-assembly. Transition between conductive and non-conductive states. Adv. Mater 1996; 8 637-641.
Szabo T, Szeri A, Dekany I. Composite graphitic nanolayers prepared by self-assembly between finely dispersed graphite oxide and a cationic polymer. Carbon 2005; 43: 87-94.
Al-Bahrani, M., Bouaissi, A., & Cree, A. (2021). Mechanical and electrical behaviors of self-sensing nanocomposite-based MWCNTs material when subjected to twist shear load. Mechanics of Advanced Materials and Structures, 28(14), 1488-1497.
Cassagneau T, Guerin F, Fendler JH. Preparation and characterization of ultrathin films layer-by-layer self-assembled from graphite oxide nanoplatelets and polymers. Langmuir 2000;16: 7318-7324.
Huang R, Suo Z, Prevost JH, et al. Inhomogeneous deformation in metallic glasses. J. Mech. Phys. Solids 2002; 50: 1011–1027.
Du XS, Xiao M,Meng YZ, et al. Novel synthesis of conductive poly(arylene disulfide)/graphite nanocomposite. Synth. Met.2004; 143: 129-132.
Grady DE. Properties of an adiabatic shear band process zone. J. Mech. Phys. Solids 1992; 40: 1197–1215.
Kocks UF, Mecking H. The physics and phenomenology of strain hardening. Prog. Mater. Sci.2003; 48: 171–273.
Al-Bahrani, M., & Cree, A. (2021). In situ detection of oil leakage by new self-sensing nanocomposite sensor containing MWCNTs. Applied Nanoscience, 11(9), 2433-2445.
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Accepted Date: 2022-08-27
Published Date: 2022-08-28
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