USE OF CARBON NANO-FIBERS IN CEMENTITIOUS MORTAR
Keywords:
Carbon, Nano-Fibers, Cementitious Mortar, MicrostructuralAbstract
Cementitious materials, especially those with higher compressive strengths, provide relatively low toughness, tensile strength and strain capacity, and are susceptible to cracking under load and restrained shrinkage effects. These drawbacks were overcome through development of multi-scale reinforcement systems comprising carbon nanofibers and microfibers for high-strength cementitious mortars. Multi-scale reinforcement of the high-performance mortar produced significant gains in the flexural strength and toughness, and abrasion and impact resistance. Microstructural investigations were also conducted in order to provide insight into the structure and failure mechanisms of high-performance cementitious mortars with multi-scale reinforcement.
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Anshar, A. M., Taba, P., and Raya, I. (2016). Kinetic and Thermodynamics Studies the Adsorption of Phenol on Activated Carbon from Rice Husk Activated by ZnCl2. Indonesian Journal of Science and Technology, 1(1), 47-60.
Awan, M. M. S., Soroushian, P., Ali, A., and Awan, M. Y. S. (2017). High-Performance Cementitious Matrix using Carbon Nanofibers. Indonesian Journal of Science and Technology, 2(1), 57-75.
Badanoiu, A., Georgescu, M., and Puri, A. (2003). The study of'DSP'binding systems by thermogravimetry and differential thermal analysis. Journal of thermal analysis and calorimetry, 74(1), 65-75.
Bayard, O., and Plé, O. (2003). Fracture mechanics of reactive powder concrete: material modelling and experimental investigations. Engineering Fracture Mechanics, 70(7), 839-851.
Beaudoin, J. J., Feldman, R. F., and Tumidajski, P. J. (1994). Pore structure of hardened Portland cement pastes and its influence on properties. Advanced Cement Based Materials, 1(5), 224-236.
Camilleri, J., Montesin, F. E., Curtis, R. V., and Ford, T. R. P. (2006). Characterization of Portland cement for use as a dental restorative material. Dental Materials, 22(6), 569-575.
Chan, Y. W., and Chu, S. H. (2004). Effect of silica fume on steel fiber bond characteristics in reactive powder concrete. Cement and Concrete Research, 34(7), 1167-1172.
Cheyrezy, M., Maret, V., and Frouin, L. (1995). Microstructural analysis of RPC (reactive powder concrete). Cement and Concrete Research, 25(7), 1491-1500.
Childs, P., Wong, A. C., Gowripalan, N., and Peng, G. D. (2007). Measurement of the coefficient of thermal expansion of ultra-high strength cementitious composites using fibre optic sensors. Cement and concrete research, 37(5), 789-795.
Collepardi, M., Corinaldesi, V., Monosi, S., and Moriconi, G. (2002). DSP materials applications and development progress. Industria Italiana del Cemento, 540-545.
Feylessoufi, A., Villieras, F., Michot, L. J., De Donato, P., Cases, J. M., and Richard, P. (1996). Water environment and nanostructural network in a reactive powder concrete. Cement and concrete composites, 18(1), 23-29.
Guerrini, G. L. (2000). Applications of high-performance fiber-reinforced cement-based composites. Applied Composite Materials, 7(2-3), 195-207.
Hammel, E., Tang, X., Trampert, M., Schmitt, T., Mauthner, K., Eder, A., and Pötschke, P. (2004). Carbon nanofibers for composite applications. Carbon, 42(5), 1153-1158.
Hu, A., Fang, Y., Young, J. F., and Oh, Y. J. (1999). Humidity dependence of apparent dielectric constant for DSP cement materials at high frequencies. Journal of the American Ceramic Society, 82(7), 1741-1747.
Jamal Shannag, M., and Hansen, W. (2000). Tensile properties of fibre-reinforced very high strength DSP mortar. Magazine of Concrete Research, 52(2), 101-108.
Lafdi, K., Fox, W., Matzek, M., and Yildiz, E. (2008). Effect of carbon nanofiber-matrix adhesion on polymeric nanocomposite properties: Part II. Journal of nanomaterials, 2008, 5.
Lawrence, J. G., Berhan, L. M., and Nadarajah, A. (2008). Elastic properties and morphology of individual carbon nanofibers. ACS nano, 2(6), 1230-1236.
Lee, M. G., Wang, Y. C., and Chiu, C. T. (2007). A preliminary study of reactive powder concrete as a new repair material. Construction and building materials, 21(1), 182-189.
Matte, V., and Moranville, M. (1999). Durability of reactive powder composites: influence of silica fume on the leaching properties of very low water/binder pastes. Cement and Concrete Composites, 21(1), 1-9.
Metaxa, Z., Konsta-Gdoutos, M., and Shah, S. (2010). Carbon nanofiber-reinforced cement-based materials. Transportation research record: Journal of the transportation research board, (2142), 114-118.
Moranville-Regourd, M. (2002). New cementitious systems and composite materials. In Key Engineering Materials (Vol 206, pp. 1841-1846). Trans Tech Publications.
Morin, V., Cohen-Tenoudji, F., Feylessoufi, A., and Richard, P. (2002). Evolution of the capillary network in a reactive powder concrete during hydration process. Cement and Concrete Research, 32(12), 1907-1914.
Richard, P., and Cheyrezy, M. (1995). Composition of reactive powder concretes. Cement and concrete research, 25(7), 1501-1511.
Roux, N., Andrade, C., and Sanjuan, M. A. (1996). Experimental study of durability of reactive powder concretes. Journal of Materials in Civil Engineering, 8(1), 1-6.
Sadiq M.M., Soroushian P., Balachandra A., Nano and/ or Micro-scale Reinforcement of High-Performance Cementitious Materials, Cement and Concrete Research, Submitted for Publication (2012b).
Sadiq M.M., Soroushian P., Balachandra A., Reinforcement of HighPerformance Cementitious Matrices with Relatively Low Volume Fractions of Graphite Nanomaterials, Cement and Concrete Composites, Submitted for Review (2012a).
Sadiq M.M., Soroushian P., Balachandra A., Reinforcing Affects of Multiwalled Carbon Nanotubes at Different Volume Fractions in High Performance Cementitious Pastes, Cement and Concrete Research, Submitted for publication (2012c).
Sanchez, F., and Ince, C. (2009). Microstructure and macroscopic properties of hybrid carbon nanofiber/silica fume cement composites. Composites Science and Technology, 69(7), 1310-1318.
Sanchez, F., Zhang, L., and Ince, C. (2009). Multi-scale performance and durability of carbon nanofiber/cement composites. Nanotechnology in Construction 3, 345-350.
Shannag, M. J., Brincker, R., and Hansen, W. (1996). Interfacial (fiber-matrix) properties of high-strength mortar (150 MPa) from fiber pullout. Materials Journal, 93(5), 480-486.
Shannag, M. J., Brincker, R., and Hansen, W. (1997). Pullout behavior of steel fibers from cement-based composites. Cement and Concrete Research, 27(6), 925-936.
Shannag, M. J., Hansen, W., and Brincker, R. (1994). Interfacial Debonding and Sliding in Brittle Cementmatrix Composites from Steel Fiber Pullout Tests. MRS Online Proceedings Library Archive, 370.
Shannag, M., Hansen, W., and Tjiptobroto, P. (1999). Interface debonding in fiber reinforced cement-matrix composites. Journal of composite materials, 33(2), 158-176.
Shofner, M. L., Lozano, K., Rodríguez‐Macías, F. J., and Barrera, E. V. (2003). Nanofiber‐reinforced polymers prepared by fused deposition modeling. Journal of applied polymer science, 89(11), 3081-3090.
Singh B., Kumar P., and Kaushik S.K., High performance composites for the new millennium, Journal of Structural Engineering (Madras), 28 (2001) 17-26.
Sun, G. K., and Young, J. F. (1993). Hydration reactions in autoclaved DSP cements. Advances in Cement research, 5(20), 163-169.
Sun, G. K., and Young, J. F. (1993). Quantitative determination of residual silica fume in DSP cement pastes by 29-SI NMR. Cement and concrete research, 23(2), 480-483.
Tjiptobroto, P., and Hansen, W. (1991). Mechanism for tensile strain hardening in high performance cement-based fiber reinforced composites. Cement and Concrete Composites, 13(4), 265-273.
Tjiptobroto, P., and Hansen, W. (1993). Model for predicting the elastic strain of frc containing high volume fractions of discontinuous fibers. Materials Journal, 90(2), 134-142.
Tjiptobroto, P., and Hansen, W. (1993). Tensile strain hardening and multiple cracking in high-performance cement-based composites containing discontinuous fibers. Materials Journal, 90(1), 16-25.
Washer, G., Fuchs, P., Graybeal, B. A., and Hartmann, J. L. (2004). Ultrasonic testing of reactive powder concrete. IEEE transactions on ultrasonics, ferroelectrics, and frequency control, 51(2), 193-201.
Wong, A. C., Childs, P. A., Berndt, R., Macken, T., Peng, G. D., and Gowripalan, N. (2007). Simultaneous measurement of shrinkage and temperature of reactive powder concrete at early-age using fibre Bragg grating sensors. Cement and Concrete Composites, 29(6), 490-497.
Xie, X. L., Mai, Y. W., and Zhou, X. P. (2005). Dispersion and alignment of carbon nanotubes in polymer matrix: a review. Materials Science and Engineering: R: Reports, 49(4), 89-112.
Young, J. F. (1996). Recent advances in the development of high performance cement-based materials. In Materials for the New Millennium (pp. 1101-1110). ASCE.
Zanni, H., Cheyrezy, M., Maret, V., Philippot, S., and Nieto, P. (1996). Investigation of hydration and pozzolanic reaction in reactive powder concrete (RPC) using 29Si NMR. Cement and Concrete Research, 26(1), 93-100.
Živica, V. (1999). Possibilities of a novel use of silica fume in mineral binding systems. Construction and Building Materials, 13(5), 271-277.
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