fbpx
Wikipedia

Nanocomposite

January 20, 2023

Nanocomposite is a multiphase solid material where one of the phases has one, two or three dimensions of less than 100 nanometers (nm) or structures having nano-scale repeat distances between the different phases that make up the material.

The idea behind Nanocomposite is to use building blocks with dimensions in nanometre range to design and create new materials with unprecedented flexibility and improvement in their physical properties.

In the broadest sense this definition can include porous media, colloids, gels and copolymers, but is more usually taken to mean the solid combination of a bulk matrix and nano-dimensional phase(s) differing in properties due to dissimilarities in structure and chemistry. The mechanical, electrical, thermal, optical, electrochemical, catalytic properties of the nanocomposite will differ markedly from that of the component materials. Size limits for these effects have been proposed:[1]

  1. <5 nm for catalytic activity
  2. <20 nm for making a hard magnetic material soft
  3. <50 nm for refractive index changes
  4. <100 nm for achieving superparamagnetism, mechanical strengthening or restricting matrix dislocation movement

Nanocomposites are found in nature, for example in the structure of the abalone shell and bone. The use of nanoparticle-rich materials long predates the understanding of the physical and chemical nature of these materials. Jose-Yacaman et al.[2] investigated the origin of the depth of colour and the resistance to acids and bio-corrosion of Maya blue paint, attributing it to a nanoparticle mechanism. From the mid-1950s nanoscale organo-clays have been used to control flow of polymer solutions (e.g. as paint viscosifiers) or the constitution of gels (e.g. as a thickening substance in cosmetics, keeping the preparations in homogeneous form). By the 1970s polymer/clay composites were the topic of textbooks,[3][4] although the term "nanocomposites" was not in common use.

In mechanical terms, nanocomposites differ from conventional composite materials due to the exceptionally high surface to volume ratio of the reinforcing phase and/or its exceptionally high aspect ratio. The reinforcing material can be made up of particles (e.g. minerals), sheets (e.g. exfoliated clay stacks) or fibres (e.g. carbon nanotubes or electrospun fibres).[5] The area of the interface between the matrix and reinforcement phase(s) is typically an order of magnitude greater than for conventional composite materials. The matrix material properties are significantly affected in the vicinity of the reinforcement. Ajayan et al.[6] note that with polymer nanocomposites, properties related to local chemistry, degree of thermoset cure, polymer chain mobility, polymer chain conformation, degree of polymer chain ordering or crystallinity can all vary significantly and continuously from the interface with the reinforcement into the bulk of the matrix.

This large amount of reinforcement surface area means that a relatively small amount of nanoscale reinforcement can have an observable effect on the macroscale properties of the composite. For example, adding carbon nanotubes improves the electrical and thermal conductivity. Other kinds of nanoparticulates may result in enhanced optical properties, dielectric properties, heat resistance or mechanical properties such as stiffness, strength and resistance to wear and damage. In general, the nano reinforcement is dispersed into the matrix during processing. The percentage by weight (called mass fraction) of the nanoparticulates introduced can remain very low (on the order of 0.5% to 5%) due to the low filler percolation threshold, especially for the most commonly used non-spherical, high aspect ratio fillers (e.g. nanometer-thin platelets, such as clays, or nanometer-diameter cylinders, such as carbon nanotubes). The orientation and arrangement of asymmetric nanoparticles, thermal property mismatch at the interface, interface density per unit volume of nanocomposite, and polydispersity of nanoparticles significantly affect the effective thermal conductivity of nanocomposites.[7]

Ceramic-matrix nanocomposites

Ceramic matrix composites (CMCs) consist of ceramic fibers embedded in a ceramic matrix. The matrix and fibers can consist of any ceramic material, including carbon and carbon fibers. The ceramic occupying most of the volume is often from the group of oxides, such as nitrides, borides, silicides, whereas the second component is often a metal. Ideally both components are finely dispersed in each other in order to elicit particular optical, electrical and magnetic properties[8] as well as tribological, corrosion-resistance and other protective properties.[9]

The binary phase diagram of the mixture should be considered in designing ceramic-metal nanocomposites and measures have to be taken to avoid a chemical reaction between both components. The last point mainly is of importance for the metallic component that may easily react with the ceramic and thereby lose its metallic character. This is not an easily obeyed constraint because the preparation of the ceramic component generally requires high process temperatures. The safest measure thus is to carefully choose immiscible metal and ceramic phases. A good example of such a combination is represented by the ceramic-metal composite of TiO2 and Cu, the mixtures of which were found immiscible over large areas in the Gibbs’ triangle of ' Cu-O-Ti.[10]

The concept of ceramic-matrix nanocomposites was also applied to thin films that are solid layers of a few nm to some tens of µm thickness deposited upon an underlying substrate and that play an important role in the functionalization of technical surfaces. Gas flow sputtering by the hollow cathode technique turned out as a rather effective technique for the preparation of nanocomposite layers. The process operates as a vacuum-based deposition technique and is associated with high deposition rates up to some µm/s and the growth of nanoparticles in the gas phase. Nanocomposite layers in the ceramics range of composition were prepared from TiO2 and Cu by the hollow cathode technique[11] that showed a high mechanical hardness, small coefficients of friction and a high resistance to corrosion.

Metal-matrix nanocomposites

Metal matrix nanocomposites can also be defined as reinforced metal matrix composites. This type of composites can be classified as continuous and non-continuous reinforced materials. One of the more important nanocomposites is Carbon nanotube metal matrix composites, which is an emerging new material that is being developed to take advantage of the high tensile strength and electrical conductivity of carbon nanotube materials.[12] Critical to the realization of CNT-MMC possessing optimal properties in these areas are the development of synthetic techniques that are (a) economically producible, (b) provide for a homogeneous dispersion of nanotubes in the metallic matrix, and (c) lead to strong interfacial adhesion between the metallic matrix and the carbon nanotubes. In addition to carbon nanotube metal matrix composites, boron nitride reinforced metal matrix composites and carbon nitride metal matrix composites are the new research areas on metal matrix nanocomposites.[13]

A recent study, comparing the mechanical properties (Young's modulus, compressive yield strength, flexural modulus and flexural yield strength) of single- and multi-walled reinforced polymeric (polypropylene fumarate—PPF) nanocomposites to tungsten disulfide nanotubes reinforced PPF nanocomposites suggest that tungsten disulfide nanotubes reinforced PPF nanocomposites possess significantly higher mechanical properties and tungsten disulfide nanotubes are better reinforcing agents than carbon nanotubes.[14] Increases in the mechanical properties can be attributed to a uniform dispersion of inorganic nanotubes in the polymer matrix (compared to carbon nanotubes that exist as micron sized aggregates) and increased crosslinking density of the polymer in the presence of tungsten disulfide nanotubes (increase in crosslinking density leads to an increase in the mechanical properties). These results suggest that inorganic nanomaterials, in general, may be better reinforcing agents compared to carbon nanotubes.

Another kind of nanocomposite is the energetic nanocomposite, generally as a hybrid sol–gel with a silica base, which, when combined with metal oxides and nano-scale aluminum powder, can form superthermite materials.[15][16][17][18]

Polymer-matrix nanocomposites

Main article: Polymer nanocomposite

In the simplest case, appropriately adding nanoparticulates to a polymer matrix can enhance its performance, often dramatically, by simply capitalizing on the nature and properties of the nanoscale filler[19] (these materials are better described by the term nanofilled polymer composites[19]). This strategy is particularly effective in yielding high performance composites, when uniform dispersion of the filler is achieved and the properties of the nanoscale filler are substantially different or better than those of the matrix. The uniformity of the dispersion is in all nanocomposites is counteracted by thermodynamically driven phase separation. Clustering of nanoscale fillers produces aggregates that serve as structural defects and result in failure. Layer-by-layer (LbL) assembly when nanometer scale layers of nanoparticulates and a polymers are added one by one. LbL composites display performance parameters 10-1000 times better that the traditional nanocomposites made by extrusion or batch-mixing.

Nanoparticles such as graphene,[20] carbon nanotubes,[21] molybdenum disulfide and tungsten disulfide are being used as reinforcing agents to fabricate mechanically strong biodegradable polymeric nanocomposites for bone tissue engineering applications. The addition of these nanoparticles in the polymer matrix at low concentrations (~0.2 weight %) cause significant improvements in the compressive and flexural mechanical properties of polymeric nanocomposites.[22][23][24] Potentially, these nanocomposites may be used as a novel, mechanically strong, light weight composite as bone implants. The results suggest that mechanical reinforcement is dependent on the nanostructure morphology, defects, dispersion of nanomaterials in the polymer matrix, and the cross-linking density of the polymer. In general, two-dimensional nanostructures can reinforce the polymer better than one-dimensional nanostructures, and inorganic nanomaterials are better reinforcing agents than carbon based nanomaterials. In addition to mechanical properties, polymer nanocomposites based on carbon nanotubes or graphene have been used to enhance a wide range of properties, giving rise to functional materials for a wide range of high added value applications in fields such as energy conversion and storage, sensing and biomedical tissue engineering.[25] For example, multi-walled carbon nanotubes based polymer nanocomposites have been used for the enhancement of the electrical conductivity.[26]

Nanoscale dispersion of filler or controlled nanostructures in the composite can introduce new physical properties and novel behaviors that are absent in the unfilled matrices. This effectively changes the nature of the original matrix[19] (such composite materials can be better described by the term genuine nanocomposites or hybrids[19]). Some examples of such new properties are fire resistance or flame retardancy,[27] and accelerated biodegradability.

A range of polymeric nanocomposites are used for biomedical applications such as tissue engineering, drug delivery, cellular therapies.[28][29] Due to unique interactions between polymer and nanoparticles, a range of property combinations can be engineered to mimic native tissue structure and properties. A range of natural and synthetic polymers are used to design polymeric nanocomposites for biomedical applications including starch, cellulose, alginate, chitosan, collagen, gelatin, and fibrin, poly(vinyl alcohol) (PVA), poly(ethylene glycol) (PEG), poly(caprolactone) (PCL), poly(lactic-co-glycolic acid) (PLGA), and poly(glycerol sebacate) (PGS). A range of nanoparticles including ceramic, polymeric, metal oxide and carbon-based nanomaterials are incorporated within polymeric network to obtain desired property combinations.[30]

Magnetic nanocomposites

Nanocomposites that can respond to an external stimulus are of increased interest due to the fact that, because of the large amount of interaction between the phase interfaces, the stimulus response can have a larger effect on the composite as a whole. The external stimulus can take many forms, such as a magnetic, electrical, or mechanical field. Specifically, magnetic nanocomposites are useful for use in these applications due to the nature of magnetic material's ability to respond both to electrical and magnetic stimuli. The penetration depth of a magnetic field is also high, leading to an increased area that the nanocomposite is affected by and therefore an increased response. In order to respond to a magnetic field, a matrix can be easily loaded with nanoparticles or nanorods The different morphologies for magnetic nanocomposite materials are vast, including matrix dispersed nanoparticles, core-shell nanoparticles, colloidal crystals, macroscale spheres, or Janus-type nanostructures.[31][32]

Magnetic nanocomposites can be utilized in a vast number of applications, including catalytic, medical, and technical. For example, palladium is a common transition metal used in catalysis reactions. Magnetic nanoparticle-supported palladium complexes can be used in catalysis to increase the efficiency of the palladium in the reaction.[33]

Magnetic nanocomposites can also be utilized in the medical field, with magnetic nanorods embedded in a polymer matrix can aid in more precise drug delivery and release. Finally, magnetic nanocomposites can be used in high frequency/high-temperature applications. For example, multi-layer structures can be fabricated for use in electronic applications. An electrodeposited Fe/Fe oxide multi-layered sample can be an example of this application of magnetic nanocomposites.[34]

In applications such as power micro-inductors where high magnetic permeability is desired at high operating frequencies.[35] The traditional micro-fabricated magnetic core materials see both decrease in permeability and high losses at high operating frequency.[36] In this case, magnetic nano composites have great potential for improving the efficiency of power electronic devices by providing relatively high permeability and low losses. For example, As Iron oxide nano particles embedded in Ni matrix enables us to mitigate those losses at high frequency.[37] The high resistive iron oxide nanoparticles helps to reduce the eddy current losses where as the Ni metal helps in attaining high permeability. DC magnetic properties such as Saturation magnetization lies between each of its constituent parts indicating that the physical properties of the materials can be altered by creating these nanocomposites.

Heat resistant nanocomposites

In the recent years nanocomposites have been designed to withstand high temperatures by the addition of Carbon Dots (CDs) in the polymer matrix. Such nanocomposites can be utilized in environments wherein high temperature resistance is a prime criterion. [38]

See also

References

  1. ^ Kamigaito, O (1991). "What can be improved by nanometer composites?". J. Jpn. Soc. Powder Powder Metall. 38 (3): 315–21. doi:10.2497/jjspm.38.315. in Kelly, A, Concise encyclopedia of composites materials, Elsevier Science Ltd, 1994
  2. ^ Jose-Yacaman, M.; Rendon, L.; Arenas, J.; Serra Puche, M. C. (1996). "Maya Blue Paint: An Ancient Nanostructured Material". Science. 273 (5272): 223–5. Bibcode:1996Sci...273..223J. doi:10.1126/science.273.5272.223. PMID 8662502. S2CID 34424830.
  3. ^ B.K.G. Theng "Formation and Properties of Clay Polymer Complexes", Elsevier, NY 1979; ISBN 978-0-444-41706-0
  4. ^ Functional Polymer Composites with Nanoclays, Editors: Yuri Lvov, Baochun Guo, Rawil F Fakhrullin, Royal Society of Chemistry, Cambridge 2017, https://pubs.rsc.org/en/content/ebook/978-1-78262-672-5
  5. ^ "What are Polymer Nanocomposites?". Coventive Composites. 2020-09-09.
  6. ^ P.M. Ajayan; L.S. Schadler; P.V. Braun (2003). Nanocomposite science and technology. Wiley. ISBN 978-3-527-30359-5.
  7. ^ Tian, Zhiting; Hu, Han; Sun, Ying (2013). "A molecular dynamics study of effective thermal conductivity in nanocomposites". Int. J. Heat Mass Transfer. 61: 577–582. doi:10.1016/j.ijheatmasstransfer.2013.02.023.
  8. ^ F. E. Kruis, H. Fissan and A. Peled (1998). "Synthesis of nanoparticles in the gas phase for electronic, optical and magnetic applications – a review". J. Aerosol Sci. 29 (5–6): 511–535. doi:10.1016/S0021-8502(97)10032-5.
  9. ^ S. Zhang; D. Sun; Y. Fu; H. Du (2003). "Recent advances of superhard nanocomposite coatings: a review". Surf. Coat. Technol. 167 (2–3): 113–119. doi:10.1016/S0257-8972(02)00903-9.
  10. ^ G. Effenberg, F. Aldinger & P. Rogl (2001). Ternary Alloys. A Comprehensive Compendium of Evaluated Constitutional Data and Phase Diagrams. Materials Science-International Services.
  11. ^ M. Birkholz; U. Albers & T. Jung (2004). "Nanocomposite layers of ceramic oxides and metals prepared by reactive gas-flow sputtering" (PDF). Surf. Coat. Technol. 179 (2–3): 279–285. doi:10.1016/S0257-8972(03)00865-X.
  12. ^ Janas, Dawid; Liszka, Barbara (2017). "Copper matrix nanocomposites based on carbon nanotubes or graphene". Mater. Chem. Front. 2: 22–35. doi:10.1039/C7QM00316A.
  13. ^ S. R. Bakshi, D. Lahiri, and A. Argawal, Carbon nanotube reinforced metal matrix composites - A Review, International Materials Reviews, vol. 55, (2010), http://web.eng.fiu.edu/agarwala/PDF/2010/12.pdf
  14. ^ Lalwani, G; Henslee, AM; Farshid, B; Parmar, P; Lin, L; Qin, YX; Kasper, FK; Mikos, AG; Sitharaman, B (September 2013). "Tungsten disulfide nanotubes reinforced biodegradable polymers for bone tissue engineering". Acta Biomaterialia. 9 (9): 8365–73. doi:10.1016/j.actbio.2013.05.018. PMC 3732565. PMID 23727293.
  15. ^ Gash, AE. "Making nanostructured pyrotechnics in a Beaker" (PDF). Retrieved 2008-09-28.
  16. ^ Gash, AE. "Energetic nanocomposites with sol-gel chemistry: synthesis, safety, and characterization, LLNL UCRL-JC-146739" (PDF). Retrieved 2008-09-28.
  17. ^ Ryan, Kevin R.; Gourley, James R.; Jones, Steven E. (2008). "Environmental anomalies at the World Trade Center: evidence for energetic materials". The Environmentalist. 29: 56–63. doi:10.1007/s10669-008-9182-4.
  18. ^ Janeta, Mateusz; John, Łukasz; Ejfler, Jolanta; Szafert, Sławomir (2014-11-24). "High-Yield Synthesis of Amido-Functionalized Polyoctahedral Oligomeric Silsesquioxanes by Using Acyl Chlorides". Chemistry: A European Journal. 20 (48): 15966–15974. doi:10.1002/chem.201404153. ISSN 1521-3765. PMID 25302846.
  19. ^ a b c d Manias, Evangelos (2007). "Nanocomposites: Stiffer by design". Nature Materials. 6 (1): 9–11. Bibcode:2007NatMa...6....9M. doi:10.1038/nmat1812. PMID 17199118.
  20. ^ Rafiee, M.A.; et al. (December 3, 2009). "Enhanced Mechanical Properties of Nanocomposites at Low Graphene Content". ACS Nano. 3 (12): 3884–3890. doi:10.1021/nn9010472. PMID 19957928.
  21. ^ Hassani, A. J.; et al. (March 1, 2014). "Preparation and characterization of polyamide 6 nanocomposites using MWCNTs based on bimetallic Co-Mo/MgO catalyst". Express Polymer Letters. 8 (3): 177–186. doi:10.3144/expresspolymlett.2014.2. S2CID 55707826.
  22. ^ Lalwani, Gaurav; Henslee, Allan M.; Farshid, Behzad; Lin, Liangjun; Kasper, F. Kurtis; Yi-, Yi-Xian; Qin, Xian; Mikos, Antonios G.; Sitharaman, Balaji (2013). "Two-dimensional nanostructure-reinforced biodegradable polymeric nanocomposites for bone tissue engineering". Biomacromolecules. 14 (3): 900–909. doi:10.1021/bm301995s. PMC 3601907. PMID 23405887.
  23. ^ Lalwani, Gaurav; Henslee, A. M.; Farshid, B; Parmar, P; Lin, L; Qin, Y. X.; Kasper, F. K.; Mikos, A. G.; Sitharaman, B (September 2013). "Tungsten disulfide nanotubes reinforced biodegradable polymers for bone tissue engineering". Acta Biomaterialia. 9 (9): 8365–8373. doi:10.1016/j.actbio.2013.05.018. PMC 3732565. PMID 23727293.
  24. ^ Zeidi, Mahdi; Kim, Chun IL; Park, Chul B. (2021). "The role of interface on the toughening and failure mechanisms of thermoplastic nanocomposites reinforced with nanofibrillated rubbers". Nanoscale. 13 (47): 20248–20280. doi:10.1039/D1NR07363J. ISSN 2040-3372. PMID 34851346. S2CID 244288401.
  25. ^ Gatti, Teresa; Vicentini, Nicola; Mba, Miriam; Menna, Enzo (2016-02-01). "Organic Functionalized Carbon Nanostructures for Functional Polymer-Based Nanocomposites". European Journal of Organic Chemistry. 2016 (6): 1071–1090. doi:10.1002/ejoc.201501411. ISSN 1099-0690.
  26. ^ Singh, BP; Singh, Deepankar; Mathur, R. B.; Dhami, T. L. (2008). "Influence of Surface Modified MWCNTs on the Mechanical, Electrical and Thermal Properties of Polyimide Nanocomposites". Nanoscale Research Letters. 3 (11): 444–453. Bibcode:2008NRL.....3..444S. doi:10.1007/s11671-008-9179-4. PMC 3244951.
  27. ^ "Flame Retardant Polymer Nanocomposites" A. B. Morgan, C. A. Wilkie (eds.), Wiley, 2007; ISBN 978-0-471-73426-0
  28. ^ Gaharwar, Akhilesh K.; Peppas, Nicholas A.; Khademhosseini, Ali (March 2014). "Nanocomposite hydrogels for biomedical applications". Biotechnology and Bioengineering. 111 (3): 441–453. doi:10.1002/bit.25160. PMC 3924876. PMID 24264728.
  29. ^ Carrow, James K.; Gaharwar, Akhilesh K. (November 2014). "Bioinspired Polymeric Nanocomposites for Regenerative Medicine". Macromolecular Chemistry and Physics. 216 (3): 248–264. doi:10.1002/macp.201400427.
  30. ^ "Developing hybrid carbon nanotube- and graphene-enhanced nanocomposite resins for the space launch system". The International Journal of Advanced Manufacturing Technology. 110 (7): 2249–2255. 2020-09-01. doi:10.1007/s00170-020-06038-7. ISSN 1433-3015.
  31. ^ Behrens, Silke; Appel, Ingo (2016). "Magnetic nanocomposites". Current Opinion in Biotechnology. 39: 89–96. doi:10.1016/j.copbio.2016.02.005. PMID 26938504.
  32. ^ Behrens, Silke (2011). "Preparation of functional magnetic nanocomposites and hybrid materials: recent progress and future directions". Nanoscale. 3 (3): 877–892. Bibcode:2011Nanos...3..877B. doi:10.1039/C0NR00634C. PMID 21165500.
  33. ^ Zhu, Yinghuai (2010). "Magnetic Nanocomposites: A New Perspective in Catalysis". ChemCatChem. 2 (4): 365–374. doi:10.1002/cctc.200900314. S2CID 96894484.
  34. ^ Varga, L.K. (2007). "Soft magnetic nanocomposites for high-frequency and high-temperature applications". Journal of Magnetism and Magnetic Materials. 316 (2): 442–447. Bibcode:2007JMMM..316..442V. doi:10.1016/j.jmmm.2007.03.180.
  35. ^ Markondeya Raj, P.; Sharma, Himani; Sitaraman, Srikrishna; Mishra, Dibyajat; Tummala, Rao (December 2017). "System Scaling With Nanostructured Power and RF Components". Proceedings of the IEEE. 105 (12): 2330 - 2346. doi:10.1109/JPROC.2017.2748520. S2CID 6587533.
  36. ^ Han, Kyu; Swaminathan, Madhavan; Pulugurtha, Raj; Sharma, Himani; Tummala, Rao; Yang, Songnan; Nair, Vijay (2016). "Magneto-Dielectric Nanocomposite for Antenna Miniaturization and SAR Reduction". IEEE Antennas and Wireless Propagation Letters. 15: 72–75. Bibcode:2016IAWPL..15...72H. doi:10.1109/LAWP.2015.2430284. S2CID 1335792.
  37. ^ Smith, Connor S.; Savliwala, Shehaab; Mills, Sara C.; Andrew, Jennifer S.; Rinaldi, Carlos; Arnold, David P. (1 January 2020). "Electro-infiltrated nickel/iron-oxide and permalloy/iron-oxide nanocomposites for integrated power inductors". Journal of Magnetism and Magnetic Materials. 493: 165718. Bibcode:2020JMMM..49365718S. doi:10.1016/j.jmmm.2019.165718. ISSN 0304-8853. S2CID 202137993.
  38. ^ Rimal, Vishal; Shishodia, Shubham; Srivastava, P.K. (2020). "Novel synthesis of high-thermal stability carbon dots and nanocomposites from oleic acid as an organic substrate". Applied Nanoscience. 10 (2): 455–464. doi:10.1007/s13204-019-01178-z. S2CID 203986488.

Further reading

  • Kumar, S. K.; Krishnamoorti, R. (2010). "Nanocomposites: Structure, Phase Behavior, and Properties". Annual Review of Chemical and Biomolecular Engineering. 1: 37–58. doi:10.1146/annurev-chembioeng-073009-100856. PMID 22432572.

January 20, 2023
nanocomposite, multiphase, solid, material, where, phases, three, dimensions, less, than, nanometers, structures, having, nano, scale, repeat, distances, between, different, phases, that, make, material, idea, behind, building, blocks, with, dimensions, nanome. Nanocomposite is a multiphase solid material where one of the phases has one two or three dimensions of less than 100 nanometers nm or structures having nano scale repeat distances between the different phases that make up the material The idea behind Nanocomposite is to use building blocks with dimensions in nanometre range to design and create new materials with unprecedented flexibility and improvement in their physical properties In the broadest sense this definition can include porous media colloids gels and copolymers but is more usually taken to mean the solid combination of a bulk matrix and nano dimensional phase s differing in properties due to dissimilarities in structure and chemistry The mechanical electrical thermal optical electrochemical catalytic properties of the nanocomposite will differ markedly from that of the component materials Size limits for these effects have been proposed 1 lt 5 nm for catalytic activity lt 20 nm for making a hard magnetic material soft lt 50 nm for refractive index changes lt 100 nm for achieving superparamagnetism mechanical strengthening or restricting matrix dislocation movementNanocomposites are found in nature for example in the structure of the abalone shell and bone The use of nanoparticle rich materials long predates the understanding of the physical and chemical nature of these materials Jose Yacaman et al 2 investigated the origin of the depth of colour and the resistance to acids and bio corrosion of Maya blue paint attributing it to a nanoparticle mechanism From the mid 1950s nanoscale organo clays have been used to control flow of polymer solutions e g as paint viscosifiers or the constitution of gels e g as a thickening substance in cosmetics keeping the preparations in homogeneous form By the 1970s polymer clay composites were the topic of textbooks 3 4 although the term nanocomposites was not in common use In mechanical terms nanocomposites differ from conventional composite materials due to the exceptionally high surface to volume ratio of the reinforcing phase and or its exceptionally high aspect ratio The reinforcing material can be made up of particles e g minerals sheets e g exfoliated clay stacks or fibres e g carbon nanotubes or electrospun fibres 5 The area of the interface between the matrix and reinforcement phase s is typically an order of magnitude greater than for conventional composite materials The matrix material properties are significantly affected in the vicinity of the reinforcement Ajayan et al 6 note that with polymer nanocomposites properties related to local chemistry degree of thermoset cure polymer chain mobility polymer chain conformation degree of polymer chain ordering or crystallinity can all vary significantly and continuously from the interface with the reinforcement into the bulk of the matrix This large amount of reinforcement surface area means that a relatively small amount of nanoscale reinforcement can have an observable effect on the macroscale properties of the composite For example adding carbon nanotubes improves the electrical and thermal conductivity Other kinds of nanoparticulates may result in enhanced optical properties dielectric properties heat resistance or mechanical properties such as stiffness strength and resistance to wear and damage In general the nano reinforcement is dispersed into the matrix during processing The percentage by weight called mass fraction of the nanoparticulates introduced can remain very low on the order of 0 5 to 5 due to the low filler percolation threshold especially for the most commonly used non spherical high aspect ratio fillers e g nanometer thin platelets such as clays or nanometer diameter cylinders such as carbon nanotubes The orientation and arrangement of asymmetric nanoparticles thermal property mismatch at the interface interface density per unit volume of nanocomposite and polydispersity of nanoparticles significantly affect the effective thermal conductivity of nanocomposites 7 Contents 1 Ceramic matrix nanocomposites 2 Metal matrix nanocomposites 3 Polymer matrix nanocomposites 4 Magnetic nanocomposites 5 Heat resistant nanocomposites 6 See also 7 References 8 Further readingCeramic matrix nanocomposites EditCeramic matrix composites CMCs consist of ceramic fibers embedded in a ceramic matrix The matrix and fibers can consist of any ceramic material including carbon and carbon fibers The ceramic occupying most of the volume is often from the group of oxides such as nitrides borides silicides whereas the second component is often a metal Ideally both components are finely dispersed in each other in order to elicit particular optical electrical and magnetic properties 8 as well as tribological corrosion resistance and other protective properties 9 The binary phase diagram of the mixture should be considered in designing ceramic metal nanocomposites and measures have to be taken to avoid a chemical reaction between both components The last point mainly is of importance for the metallic component that may easily react with the ceramic and thereby lose its metallic character This is not an easily obeyed constraint because the preparation of the ceramic component generally requires high process temperatures The safest measure thus is to carefully choose immiscible metal and ceramic phases A good example of such a combination is represented by the ceramic metal composite of TiO2 and Cu the mixtures of which were found immiscible over large areas in the Gibbs triangle of Cu O Ti 10 The concept of ceramic matrix nanocomposites was also applied to thin films that are solid layers of a few nm to some tens of µm thickness deposited upon an underlying substrate and that play an important role in the functionalization of technical surfaces Gas flow sputtering by the hollow cathode technique turned out as a rather effective technique for the preparation of nanocomposite layers The process operates as a vacuum based deposition technique and is associated with high deposition rates up to some µm s and the growth of nanoparticles in the gas phase Nanocomposite layers in the ceramics range of composition were prepared from TiO2 and Cu by the hollow cathode technique 11 that showed a high mechanical hardness small coefficients of friction and a high resistance to corrosion Metal matrix nanocomposites EditThis section needs expansion You can help by adding to it November 2008 Metal matrix nanocomposites can also be defined as reinforced metal matrix composites This type of composites can be classified as continuous and non continuous reinforced materials One of the more important nanocomposites is Carbon nanotube metal matrix composites which is an emerging new material that is being developed to take advantage of the high tensile strength and electrical conductivity of carbon nanotube materials 12 Critical to the realization of CNT MMC possessing optimal properties in these areas are the development of synthetic techniques that are a economically producible b provide for a homogeneous dispersion of nanotubes in the metallic matrix and c lead to strong interfacial adhesion between the metallic matrix and the carbon nanotubes In addition to carbon nanotube metal matrix composites boron nitride reinforced metal matrix composites and carbon nitride metal matrix composites are the new research areas on metal matrix nanocomposites 13 A recent study comparing the mechanical properties Young s modulus compressive yield strength flexural modulus and flexural yield strength of single and multi walled reinforced polymeric polypropylene fumarate PPF nanocomposites to tungsten disulfide nanotubes reinforced PPF nanocomposites suggest that tungsten disulfide nanotubes reinforced PPF nanocomposites possess significantly higher mechanical properties and tungsten disulfide nanotubes are better reinforcing agents than carbon nanotubes 14 Increases in the mechanical properties can be attributed to a uniform dispersion of inorganic nanotubes in the polymer matrix compared to carbon nanotubes that exist as micron sized aggregates and increased crosslinking density of the polymer in the presence of tungsten disulfide nanotubes increase in crosslinking density leads to an increase in the mechanical properties These results suggest that inorganic nanomaterials in general may be better reinforcing agents compared to carbon nanotubes Another kind of nanocomposite is the energetic nanocomposite generally as a hybrid sol gel with a silica base which when combined with metal oxides and nano scale aluminum powder can form superthermite materials 15 16 17 18 Polymer matrix nanocomposites EditMain article Polymer nanocomposite In the simplest case appropriately adding nanoparticulates to a polymer matrix can enhance its performance often dramatically by simply capitalizing on the nature and properties of the nanoscale filler 19 these materials are better described by the term nanofilled polymer composites 19 This strategy is particularly effective in yielding high performance composites when uniform dispersion of the filler is achieved and the properties of the nanoscale filler are substantially different or better than those of the matrix The uniformity of the dispersion is in all nanocomposites is counteracted by thermodynamically driven phase separation Clustering of nanoscale fillers produces aggregates that serve as structural defects and result in failure Layer by layer LbL assembly when nanometer scale layers of nanoparticulates and a polymers are added one by one LbL composites display performance parameters 10 1000 times better that the traditional nanocomposites made by extrusion or batch mixing Nanoparticles such as graphene 20 carbon nanotubes 21 molybdenum disulfide and tungsten disulfide are being used as reinforcing agents to fabricate mechanically strong biodegradable polymeric nanocomposites for bone tissue engineering applications The addition of these nanoparticles in the polymer matrix at low concentrations 0 2 weight cause significant improvements in the compressive and flexural mechanical properties of polymeric nanocomposites 22 23 24 Potentially these nanocomposites may be used as a novel mechanically strong light weight composite as bone implants The results suggest that mechanical reinforcement is dependent on the nanostructure morphology defects dispersion of nanomaterials in the polymer matrix and the cross linking density of the polymer In general two dimensional nanostructures can reinforce the polymer better than one dimensional nanostructures and inorganic nanomaterials are better reinforcing agents than carbon based nanomaterials In addition to mechanical properties polymer nanocomposites based on carbon nanotubes or graphene have been used to enhance a wide range of properties giving rise to functional materials for a wide range of high added value applications in fields such as energy conversion and storage sensing and biomedical tissue engineering 25 For example multi walled carbon nanotubes based polymer nanocomposites have been used for the enhancement of the electrical conductivity 26 Nanoscale dispersion of filler or controlled nanostructures in the composite can introduce new physical properties and novel behaviors that are absent in the unfilled matrices This effectively changes the nature of the original matrix 19 such composite materials can be better described by the term genuine nanocomposites or hybrids 19 Some examples of such new properties are fire resistance or flame retardancy 27 and accelerated biodegradability A range of polymeric nanocomposites are used for biomedical applications such as tissue engineering drug delivery cellular therapies 28 29 Due to unique interactions between polymer and nanoparticles a range of property combinations can be engineered to mimic native tissue structure and properties A range of natural and synthetic polymers are used to design polymeric nanocomposites for biomedical applications including starch cellulose alginate chitosan collagen gelatin and fibrin poly vinyl alcohol PVA poly ethylene glycol PEG poly caprolactone PCL poly lactic co glycolic acid PLGA and poly glycerol sebacate PGS A range of nanoparticles including ceramic polymeric metal oxide and carbon based nanomaterials are incorporated within polymeric network to obtain desired property combinations 30 Magnetic nanocomposites EditNanocomposites that can respond to an external stimulus are of increased interest due to the fact that because of the large amount of interaction between the phase interfaces the stimulus response can have a larger effect on the composite as a whole The external stimulus can take many forms such as a magnetic electrical or mechanical field Specifically magnetic nanocomposites are useful for use in these applications due to the nature of magnetic material s ability to respond both to electrical and magnetic stimuli The penetration depth of a magnetic field is also high leading to an increased area that the nanocomposite is affected by and therefore an increased response In order to respond to a magnetic field a matrix can be easily loaded with nanoparticles or nanorods The different morphologies for magnetic nanocomposite materials are vast including matrix dispersed nanoparticles core shell nanoparticles colloidal crystals macroscale spheres or Janus type nanostructures 31 32 Magnetic nanocomposites can be utilized in a vast number of applications including catalytic medical and technical For example palladium is a common transition metal used in catalysis reactions Magnetic nanoparticle supported palladium complexes can be used in catalysis to increase the efficiency of the palladium in the reaction 33 Magnetic nanocomposites can also be utilized in the medical field with magnetic nanorods embedded in a polymer matrix can aid in more precise drug delivery and release Finally magnetic nanocomposites can be used in high frequency high temperature applications For example multi layer structures can be fabricated for use in electronic applications An electrodeposited Fe Fe oxide multi layered sample can be an example of this application of magnetic nanocomposites 34 In applications such as power micro inductors where high magnetic permeability is desired at high operating frequencies 35 The traditional micro fabricated magnetic core materials see both decrease in permeability and high losses at high operating frequency 36 In this case magnetic nano composites have great potential for improving the efficiency of power electronic devices by providing relatively high permeability and low losses For example As Iron oxide nano particles embedded in Ni matrix enables us to mitigate those losses at high frequency 37 The high resistive iron oxide nanoparticles helps to reduce the eddy current losses where as the Ni metal helps in attaining high permeability DC magnetic properties such as Saturation magnetization lies between each of its constituent parts indicating that the physical properties of the materials can be altered by creating these nanocomposites Heat resistant nanocomposites EditIn the recent years nanocomposites have been designed to withstand high temperatures by the addition of Carbon Dots CDs in the polymer matrix Such nanocomposites can be utilized in environments wherein high temperature resistance is a prime criterion 38 See also Edit Science portal Technology portalHybrid materials AquameltReferences Edit Kamigaito O 1991 What can be improved by nanometer composites J Jpn Soc Powder Powder Metall 38 3 315 21 doi 10 2497 jjspm 38 315 in Kelly A Concise encyclopedia of composites materials Elsevier Science Ltd 1994 Jose Yacaman M Rendon L Arenas J Serra Puche M C 1996 Maya Blue Paint An Ancient Nanostructured Material Science 273 5272 223 5 Bibcode 1996Sci 273 223J doi 10 1126 science 273 5272 223 PMID 8662502 S2CID 34424830 B K G Theng Formation and Properties of Clay Polymer Complexes Elsevier NY 1979 ISBN 978 0 444 41706 0 Functional Polymer Composites with Nanoclays Editors Yuri Lvov Baochun Guo Rawil F Fakhrullin Royal Society of Chemistry Cambridge 2017 https pubs rsc org en content ebook 978 1 78262 672 5 What are Polymer Nanocomposites Coventive Composites 2020 09 09 P M Ajayan L S Schadler P V Braun 2003 Nanocomposite science and technology Wiley ISBN 978 3 527 30359 5 Tian Zhiting Hu Han Sun Ying 2013 A molecular dynamics study of effective thermal conductivity in nanocomposites Int J Heat Mass Transfer 61 577 582 doi 10 1016 j ijheatmasstransfer 2013 02 023 F E Kruis H Fissan and A Peled 1998 Synthesis of nanoparticles in the gas phase for electronic optical and magnetic applications a review J Aerosol Sci 29 5 6 511 535 doi 10 1016 S0021 8502 97 10032 5 S Zhang D Sun Y Fu H Du 2003 Recent advances of superhard nanocomposite coatings a review Surf Coat Technol 167 2 3 113 119 doi 10 1016 S0257 8972 02 00903 9 G Effenberg F Aldinger amp P Rogl 2001 Ternary Alloys A Comprehensive Compendium of Evaluated Constitutional Data and Phase Diagrams Materials Science International Services M Birkholz U Albers amp T Jung 2004 Nanocomposite layers of ceramic oxides and metals prepared by reactive gas flow sputtering PDF Surf Coat Technol 179 2 3 279 285 doi 10 1016 S0257 8972 03 00865 X Janas Dawid Liszka Barbara 2017 Copper matrix nanocomposites based on carbon nanotubes or graphene Mater Chem Front 2 22 35 doi 10 1039 C7QM00316A S R Bakshi D Lahiri and A Argawal Carbon nanotube reinforced metal matrix composites A Review International Materials Reviews vol 55 2010 http web eng fiu edu agarwala PDF 2010 12 pdf Lalwani G Henslee AM Farshid B Parmar P Lin L Qin YX Kasper FK Mikos AG Sitharaman B September 2013 Tungsten disulfide nanotubes reinforced biodegradable polymers for bone tissue engineering Acta Biomaterialia 9 9 8365 73 doi 10 1016 j actbio 2013 05 018 PMC 3732565 PMID 23727293 Gash AE Making nanostructured pyrotechnics in a Beaker PDF Retrieved 2008 09 28 Gash AE Energetic nanocomposites with sol gel chemistry synthesis safety and characterization LLNL UCRL JC 146739 PDF Retrieved 2008 09 28 Ryan Kevin R Gourley James R Jones Steven E 2008 Environmental anomalies at the World Trade Center evidence for energetic materials The Environmentalist 29 56 63 doi 10 1007 s10669 008 9182 4 Janeta Mateusz John Lukasz Ejfler Jolanta Szafert Slawomir 2014 11 24 High Yield Synthesis of Amido Functionalized Polyoctahedral Oligomeric Silsesquioxanes by Using Acyl Chlorides Chemistry A European Journal 20 48 15966 15974 doi 10 1002 chem 201404153 ISSN 1521 3765 PMID 25302846 a b c d Manias Evangelos 2007 Nanocomposites Stiffer by design Nature Materials 6 1 9 11 Bibcode 2007NatMa 6 9M doi 10 1038 nmat1812 PMID 17199118 Rafiee M A et al December 3 2009 Enhanced Mechanical Properties of Nanocomposites at Low Graphene Content ACS Nano 3 12 3884 3890 doi 10 1021 nn9010472 PMID 19957928 Hassani A J et al March 1 2014 Preparation and characterization of polyamide 6 nanocomposites using MWCNTs based on bimetallic Co Mo MgO catalyst Express Polymer Letters 8 3 177 186 doi 10 3144 expresspolymlett 2014 2 S2CID 55707826 Lalwani Gaurav Henslee Allan M Farshid Behzad Lin Liangjun Kasper F Kurtis Yi Yi Xian Qin Xian Mikos Antonios G Sitharaman Balaji 2013 Two dimensional nanostructure reinforced biodegradable polymeric nanocomposites for bone tissue engineering Biomacromolecules 14 3 900 909 doi 10 1021 bm301995s PMC 3601907 PMID 23405887 Lalwani Gaurav Henslee A M Farshid B Parmar P Lin L Qin Y X Kasper F K Mikos A G Sitharaman B September 2013 Tungsten disulfide nanotubes reinforced biodegradable polymers for bone tissue engineering Acta Biomaterialia 9 9 8365 8373 doi 10 1016 j actbio 2013 05 018 PMC 3732565 PMID 23727293 Zeidi Mahdi Kim Chun IL Park Chul B 2021 The role of interface on the toughening and failure mechanisms of thermoplastic nanocomposites reinforced with nanofibrillated rubbers Nanoscale 13 47 20248 20280 doi 10 1039 D1NR07363J ISSN 2040 3372 PMID 34851346 S2CID 244288401 Gatti Teresa Vicentini Nicola Mba Miriam Menna Enzo 2016 02 01 Organic Functionalized Carbon Nanostructures for Functional Polymer Based Nanocomposites European Journal of Organic Chemistry 2016 6 1071 1090 doi 10 1002 ejoc 201501411 ISSN 1099 0690 Singh BP Singh Deepankar Mathur R B Dhami T L 2008 Influence of Surface Modified MWCNTs on the Mechanical Electrical and Thermal Properties of Polyimide Nanocomposites Nanoscale Research Letters 3 11 444 453 Bibcode 2008NRL 3 444S doi 10 1007 s11671 008 9179 4 PMC 3244951 Flame Retardant Polymer Nanocomposites A B Morgan C A Wilkie eds Wiley 2007 ISBN 978 0 471 73426 0 Gaharwar Akhilesh K Peppas Nicholas A Khademhosseini Ali March 2014 Nanocomposite hydrogels for biomedical applications Biotechnology and Bioengineering 111 3 441 453 doi 10 1002 bit 25160 PMC 3924876 PMID 24264728 Carrow James K Gaharwar Akhilesh K November 2014 Bioinspired Polymeric Nanocomposites for Regenerative Medicine Macromolecular Chemistry and Physics 216 3 248 264 doi 10 1002 macp 201400427 Developing hybrid carbon nanotube and graphene enhanced nanocomposite resins for the space launch system The International Journal of Advanced Manufacturing Technology 110 7 2249 2255 2020 09 01 doi 10 1007 s00170 020 06038 7 ISSN 1433 3015 Behrens Silke Appel Ingo 2016 Magnetic nanocomposites Current Opinion in Biotechnology 39 89 96 doi 10 1016 j copbio 2016 02 005 PMID 26938504 Behrens Silke 2011 Preparation of functional magnetic nanocomposites and hybrid materials recent progress and future directions Nanoscale 3 3 877 892 Bibcode 2011Nanos 3 877B doi 10 1039 C0NR00634C PMID 21165500 Zhu Yinghuai 2010 Magnetic Nanocomposites A New Perspective in Catalysis ChemCatChem 2 4 365 374 doi 10 1002 cctc 200900314 S2CID 96894484 Varga L K 2007 Soft magnetic nanocomposites for high frequency and high temperature applications Journal of Magnetism and Magnetic Materials 316 2 442 447 Bibcode 2007JMMM 316 442V doi 10 1016 j jmmm 2007 03 180 Markondeya Raj P Sharma Himani Sitaraman Srikrishna Mishra Dibyajat Tummala Rao December 2017 System Scaling With Nanostructured Power and RF Components Proceedings of the IEEE 105 12 2330 2346 doi 10 1109 JPROC 2017 2748520 S2CID 6587533 Han Kyu Swaminathan Madhavan Pulugurtha Raj Sharma Himani Tummala Rao Yang Songnan Nair Vijay 2016 Magneto Dielectric Nanocomposite for Antenna Miniaturization and SAR Reduction IEEE Antennas and Wireless Propagation Letters 15 72 75 Bibcode 2016IAWPL 15 72H doi 10 1109 LAWP 2015 2430284 S2CID 1335792 Smith Connor S Savliwala Shehaab Mills Sara C Andrew Jennifer S Rinaldi Carlos Arnold David P 1 January 2020 Electro infiltrated nickel iron oxide and permalloy iron oxide nanocomposites for integrated power inductors Journal of Magnetism and Magnetic Materials 493 165718 Bibcode 2020JMMM 49365718S doi 10 1016 j jmmm 2019 165718 ISSN 0304 8853 S2CID 202137993 Rimal Vishal Shishodia Shubham Srivastava P K 2020 Novel synthesis of high thermal stability carbon dots and nanocomposites from oleic acid as an organic substrate Applied Nanoscience 10 2 455 464 doi 10 1007 s13204 019 01178 z S2CID 203986488 Further reading EditKumar S K Krishnamoorti R 2010 Nanocomposites Structure Phase Behavior and Properties Annual Review of Chemical and Biomolecular Engineering 1 37 58 doi 10 1146 annurev chembioeng 073009 100856 PMID 22432572 Retrieved from https en wikipedia org w index php title Nanocomposite amp oldid 1132536407, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.