Journal of
Chemical Engineering and Materials Science

  • Abbreviation: J. Chem. Eng. Mater. Sci.
  • Language: English
  • ISSN: 2141-6605
  • DOI: 10.5897/JCEMS
  • Start Year: 2010
  • Published Articles: 95

Full Length Research Paper

Effect of nano-carbon percentage on properties of composite materials

Ali Anvari
  • Ali Anvari
  • Department of Mechanical and Aerospace Engineering, University of Missouri-Columbia, USA.
  • Google Scholar

  •  Received: 28 December 2016
  •  Accepted: 06 July 2017
  •  Published: 31 July 2017


Barbero EJ and Cosso FA (2014). Determination of Material Parameters for Discrete Damage Mechanics Analysis of Carbon-Epoxy Laminates. Composites: Part B 56:638-646.


Chauhan P, Osternman M, Pecht M (2012). Canary Approach For Monitoring BGA Interconnect Reliability Under Temperature Cycling. CALCE Electronic Products and Systems Center, University of Chow WS, Leu YY, Ishak ZAM (2016). Mechanical, Thermal and Morphological Properties of Injection Molded Poly (Lactic acid)/Calcium Carbonate Nanocomposites. Periodica Polytechnica, Mech.Eng. 60(1):15-20.


Functionalized Carbon Nanotube Reinforced Carbon Fiber Composites. Texas A & M University, college station, Texas 77844-3012.


Huang X (2009). Fabrication and Properties of Carbon Fibers. Materials 2:2369-2403.


Jo HS, Lee GW (2014). Thermal Expansion Coefficient and Young's Modulus of Silica- Reinforced Epoxy Composite. Int. J. Chem. Mol. Nucl. Mater. Metallurgical Eng. 8(11):1188-1191.


Karadeniz ZH (2005). A numerical study on the thermal expansion coefficients of fiber reinforced composite materials. Master of Science Thesis in mechanical engineering, Energy Program, Dokuz Eylul University.


Maryland, College Park, MD 20742.


Meszaros L, Turcsan T (2014). Development and mechanical properties of carbon fibre reinforced EP/VE hybrid composite systems. Periodica Polytechnica, Mec. Eng. 58(2):127-133.


Misak HE, Sabelkin V, Mall S, Kladitis PE (2013). Thermal fatigue and hypothermal atomic oxygen exposure behavior of carbon nanotube wire. Carbon 57:42-49.


Park a,* SY, Choi b HS, Choi a WJ, and Kwon a H 2012). Effect of vacuum thermal cyclic exposures on unidirectional carbon fiber/epoxy composites for low earth orbit space applications. Composites: Part B 43, pp. 726-738.


Ramanujam N, Vaddadi P, Nakamura T, Singh RP (2008). Interlaminar fatigue crack growth of cross-ply composites under thermal cycles. Composite Structures 85:175-187.


Ray BC and Rathore D (2014). Durability and integrity studies of environmentally conditioned interfaces in fibrous polymeric composites: Critical concepts and comments. Department of Metallurgical and Materials Engineering, National Institute of Technology, Rourkela-769008, India.


Savkin A, Andronik A, Abhilash R (2015). Crack Closure Detection Using Photometrical Analysis. Periodica Polytechnica, Mech. Eng. 59(3):114-119.


Song K, Zhang Y, Meng J, Green EC, Tajaddod N, Li H, Minus ML (2013). Structural Polymer-Based Carbon Nanotube Composite Fibers: Understanding the Processing Structure-Performance Relationship. Materials 6:2543-2577.


Voicu R (2012). Structural Characterization and Mechanical Behaviour of Carbon Fiber/epoxy Composite for Aeronautical Field. Materiale Plastice 49(1):34-40.


Wilkerson J, Daniel A, and Daniel D (2007). Fatigue Characterization of Functionalized Carbon Nanotube Reinforced Carbon Fiber Composites. Texas A & M University, college station, Texas 77844-3012.