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Amani, Y., Mohammadi, A., Raofi Rad, H. (2018). Effect of Cu-nanoparticles on Anticorrosion Performance of Polymeric Films. Electronic and Cyber Defense, 9(34), 64-71.
Yaser Amani; Abbas Mohammadi; Hosein Raofi Rad. "Effect of Cu-nanoparticles on Anticorrosion Performance of Polymeric Films". Electronic and Cyber Defense, 9, 34, 2018, 64-71.
Amani, Y., Mohammadi, A., Raofi Rad, H. (2018). 'Effect of Cu-nanoparticles on Anticorrosion Performance of Polymeric Films', Electronic and Cyber Defense, 9(34), pp. 64-71.
Amani, Y., Mohammadi, A., Raofi Rad, H. Effect of Cu-nanoparticles on Anticorrosion Performance of Polymeric Films. Electronic and Cyber Defense, 2018; 9(34): 64-71.

Effect of Cu-nanoparticles on Anticorrosion Performance of Polymeric Films

علوم و فنون بسته‌بندی
Article 6, Volume 9, Issue 34, November 2018, Pages 64-71    PDF (959.45 K)
Document Type: Original Article
Authors
Yaser Amani* 1; Abbas Mohammadi2; Hosein Raofi Rad3
1Master of Polymer Processing Engineering, Beasat Company, Qom, Iran
2Ph.D. in Chemical Engineering, Beasat Company, Qom, Iran
3MSc in Chemical Engineering Biotechnology, Beasat Company, Qom, Iran
Receive Date: 21 April 2018Revise Date: 23 August 2018Accept Date: 21 September 2018 
Abstract
The present paper seeks to study the active polymeric film with corrosion protection capability. Due to the reactivity of their active component with corrosive gaseous agents, these materials are called active polymers. The structure of these compounds consists of a polymeric substrate (such as polyethylene, polypropylene or polystyrene) containing copper nanoparticles (Cu- nanoparticles) that, by reacting and neutralizing corrosive gases, prevent the penetration of undesirable agents into the packaging. Cu-nanocomposites do not contaminate the protected parts. The most important feature of these films is the ability to remove and neutralize the corrosive gases in the packaging atmosphere.  Also, these compounds simultaneously, using a single film, have the ability to protect against corrosion, moisture and the dangers of static electricity accumulation over a relatively long period (more than 7 years). Despite the possibility of using conventional manufacturing methods, today efforts are being made to develop production methods for easier application of these films in various industries. In this work, basic concepts, applications, production techniques, anticorrosion and electrical properties, as well as the governing mechanism on the performance of films containing copper nanoparticles are described.
Keywords
Cu nanoparticles; Corrosion; Active Polymeric Films; Packaging; Polymeric Nano Composite
References
1. Goldade V.A., Pinchuk L.S., Makarevich A.V., Kestelman V.N., )2005(, “Plastic for Corrosion Inhibition,” Germany, Springer.

2. Kumar A.M., Khan A., Suleiman R., Qamar M., Saravanan S., Dafalla H., )2018(, “Bifunctional CuO/TiO2 nanocomposite as nanofiller for improved corrosion resistance and antibacterial protection,” Progress in Organic Coatings, Vol. 114, 9-18.

3. Aly K., Younis O., Mahross  M., Tsutsum O., Mohamed M., Sayed M., )2018(, “Novel conducting polymeric nanocomposites embedded with nanoclay: synthesis, photoluminescence, and corrosion protectionperformance,” Polym. Jour.,  Vol. 18, 1-14.

4. Merachtsaki D., Xidas P., Giannakoudakis P., Triantafyllidis K., Spathis P.,  )2017(, “Corrosion Protection of Steel by Epoxy-Organoclay Nanocomposite Coatings,” Coatings,  Vol. 7, 84-103.

5. Saji V.S., Cook R., )2012(, "Corrosion protection and control using nanomaterials," United Kingdom, Woodhead publications.

6. Franey P., Sutton D., )2006(, “Static Intercept* Technology: A New Packaging Platform for Corrosion and ESD Protection,” Bell Labs Tech, Vol. 11, 137-146.

7. Bastidas D. , Cano E., Mora E., )2005(, “ Volatile corrosion inhibitors: a review,” Anti-Corros. Methods & Mater., Vol. 52, 71-77.

8. Xue B., Jiang Y. Liu D., )2010(, “Preparation and Characterization of a Novel Anticorrosion Material: Cu/LLDPE Nanocomposites,” Materials Transactions, Vol. 52, No. 1, 96-101.

9. Nicolais L., Carotenuto G., )2005(, “Metal-Polymer nanocomposites, New Jersey,” John Wiley & Sons Publications.

10. Xue B., Li F., Xing Y., )2011(, “Preparation of Cu/OMMT/LLDPE nanocomposites and synergistic effect study of two different nano materials in polymer matrix,” Polym. Bull., Vol. 67, 1463–1481.

11. Luyt A.S., Molefi J.A., Krump H., )2011(,“Thermal, mechanical and electrical properties of copper powder filled low-density and linear low-density polyethylene composites,” Polym. Degradation and Stability, Vol. 91, 1629–1636.

12. Alvarez M.P., Poblete V.H., Pilleux M.E., )2008(.“Submicron copper-low-density polyethylene Conducting composites: Structural, electrical, and percolation threshold.” J. Applied polym. Science., Vol. 99, 3005–3008.

13. Poblete V.H., Alvarez M.P., Fuenzalida V.M., (2009), “Conductive copper-PMMA Nanocomposites: Microstructure, electrical behavior, and percolation threshold as a function of metal filler concentration.” Polym. Compos., Vol. 30, 328–333.

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