Open Access
MATEC Web Conf.
Volume 103, 2017
International Symposium on Civil and Environmental Engineering 2016 (ISCEE 2016)
Article Number 01023
Number of page(s) 10
Section Sustainable and Advanced Construction Materials
Published online 05 April 2017
  1. O. Kayali and B. Zhu, Corrosion performance of medium-strength and silica fume high-strength reinforced concrete in a chloride solution, Cement and Concrete Composition, 27, 117–124 (2005) [CrossRef] [Google Scholar]
  2. M. Maes and N. De Belie, Resistance of concrete and mortar against combined attack of chloride and sodium sulphate, Cement and Concrete Composition, 53, 59–72 (2014) [CrossRef] [Google Scholar]
  3. C. Andrade, R. d’Andrea and N. Rebolledo, Chloride ion penetration in concrete: The reaction factor in the electrical resistivity model, Cement and Concrete Composition, 47, 41–46 (2013) [CrossRef] [Google Scholar]
  4. Federal Highway Administration, Building more durable bridges, FOCUS Federal Highway Administration, Washington DC, United States, (2001) [Google Scholar]
  5. BRE Centre for Concrete Construction, Guide to the maintenance, repair and monitoring of reinforced concrete structures, DME Report 4, Watford, United Kingdom, (2001) [Google Scholar]
  6. B.E. Graybeal and J.L. Hartmann, Strength and durability of ultra-high performance concrete, 3rd International Symposium on High Performance Concrete, PCI, Orlando, (2003) Florida. [Google Scholar]
  7. B.E. Graybeal and J. Tanesi, Durability of an ultrahigh-performance concrete, J. of Materials in Civil Engineering, 19(10), 848–854 (2007) [CrossRef] [Google Scholar]
  8. P.R. Prem, B.H. Bharatkumar and N.R. Iyer, Mechanical properties of ultra high performance concrete, Int. Scholarly and Scientific Research and Innovation, 6(8), 676–685 (2012) [Google Scholar]
  9. R. Yu, P. Spiesz and H.J.H. Brouwers, Mix design and properties assessment of ultrahigh performance fibre reinforced concrete (UHPFRC), Cement and Concrete Research, 56, 29–39 (2014) [CrossRef] [Google Scholar]
  10. A.S. El-Dieb, Mechanical, durability and microstructural characteristics of ultrahighstrength self-compacting concrete incorporating steel fibres, Material and Design, 30, 4286–4292 (2009) [Google Scholar]
  11. B.A. Tayeh, B.H. Abu Bakar, M.A. Megat Johari and Y.L. Voo, Mechanical and permeability properties of the interface between normal concrete substrate and ultrahigh performance fibre concrete overlay, Construction and Building Materials, 36, 538–548 (2012) [CrossRef] [Google Scholar]
  12. M. Schmidt, E. Fehling, C. Geisenhanslüke, Ultra high performance concrete (UHPC), structural material and engineering series, Proc. Symposium on Ultra High Performance Concrete, 3, Kassel, Germany, (2004) [Google Scholar]
  13. E. Ghafari, H. Costa, E. Júlio, A. Portugal and L. Durães, The effect of nanosilica addition on flowability, strength and transport properties of ultra-high performance concrete, Materials and Design, 59, 1–9 (2014) [CrossRef] [Google Scholar]
  14. N. Randl, T. Steiner, S. Ofner, E. Baumgartner and T. Mészöly, Development of UHPC mixtures from an ecological point view, Construction and Building Materials, 67, 373–378 (2014) [CrossRef] [Google Scholar]
  15. R. Yu, P. Spiesz and H.J.H. Brouwers, Effect of nano-silica on the hydration and microstructure development of ultra-high performance concrete (UHPC) with a low binder amount, Construction and Building Materials, 65, 140–150 (2014) [CrossRef] [Google Scholar]
  16. M. Alkaysi, S. El-Tawil, Z. Liu and W. Hansen, Effects of silica powder and cement type on durability of ultra high performance concrete (UHPC), Cement and Concrete Composites, 66(10), 47–56 (2016) [Google Scholar]
  17. A.N. Mohammed, M.A.M. Johari, A.M. Zeyad, B.A. Tayeh and M.O. Yusuf, Improving the engineering and fluid transport properties of ultra-high strength concrete utilizing ultrafine palm oil fuel ash, J. of Advanced Concrete Technology, 12, 127–137 (2014) [CrossRef] [Google Scholar]
  18. M.J.M. Faizal, M.S. Hamidah and M.S. Muhd Norhasri, Strength and chloride content of nanoclayed ultra-high performance concrete, Structures, Materials and Construction Engineering, DAKAM Publishing (2014) [Google Scholar]
  19. M.J. Mohd Faizal, M.S. Hamidah, M.S. Muhd Norhasri, I. Noorli and M.P. Mohamad Ezad Hafez, Chloride permeability of nanoclayed ultra-high performance concrete, Proc. of Int. Civil and Infrastructure Engineering Conf., Springer Singapore, 613–625 (2015) [Google Scholar]
  20. M.J. Mohd Faizal, M.S. Hamidah, M.S. Muhd Norhasri and I. Noorli, Effect of clay as a nanomaterial on corrosion potential of steel reinforcement embedded in ultra-high performance concrete, Proc. of Int. Civil and Infrastructure Engineering Conf., Springer Singapore, 679–689 (2016). [Google Scholar]
  21. C. Shi, Effect of mixing proportion of concrete on its electrical conductivity and the rapid chloride permeability test (ASTM C1202 or ASSHTO T227) results, Cement and Concrete Research, 34(3), 537–545 (2004) [CrossRef] [Google Scholar]
  22. M.S. Ahmed, O. Kayali and W. Anderson, Evaluation of binary and ternary blends of pozzolanic materials using the rapid chloride permeability test, J. of Materials in Civil Engineering, 21(9), 446–453 (2009) [CrossRef] [Google Scholar]
  23. K. Krishnakumar, S. Bhaskar and K. Parthlbah, Evaluation of chloride in OPC concrete by silver nitrate solution spray method, Int. J. of Chemical Technology Research, 6(5), 2676–2882 (2004) [Google Scholar]
  24. M.T. Bassuoni, M.L. Nehdi, and T.R. Greenough, Enhancing the reliability of evaluating chloride ingress in concrete using ASTM C1202 rapid chloride penetrability test, J. of ASTM International, 3(3), 1–13 (2006) [Google Scholar]
  25. M.R. Nooken and R.D. Hooton, Dependence of rate of absorption on degree of saturation of concrete, Journal of Cememt, Concrete and Aggregates (CCA), 24(1), 20–24 (2002) [CrossRef] [Google Scholar]
  26. ASTM C1202-07, Standard test method for the electrical indication of concrete’s ability to resist chloride ion penetration, American Society of Testing and Materials, Pennsylvania, (2007) [Google Scholar]
  27. C. Vernet, UHPC microstructure and related durability performance laboratory assessment and field experience examples, Proc. of the Int. Symposium on High Performance Concrete, Orlando, (2003) [Google Scholar]
  28. O. Bonneau, C. Vernet, M. Moranville and P.C. Aïtchin, Characterization of the granular packing and percolation threshold of reactive powder concrete, Cement and Concrete Research, 26(11), 1639–1648 (2000) [Google Scholar]
  29. S. Ahmad, Development on test methods for assessment of concrete durability for use in performance-based specification, Master Thesis, University of Toronto, Canada, (2010) [Google Scholar]
  30. G. Dhinakaran, S. Thilgavathi and J. Venkataramana, Compressive strength and chloride resistance of metakaolin concrete, KSCE J. of Civil Engineering, 16(7), 1209–1217 (2012) [CrossRef] [Google Scholar]
  31. H. Shouky, M.F. Kokkata, S.A. Abo-El-Enein, M.S. Morsy, S.S. Shebl, Enhanced physical, mechanical and microstructural properties of lightweight vermiculite cement composites modified with nano metakaolin, Construction and Building Materials, 112, 276–283 (2016) [CrossRef] [Google Scholar]

Current usage metrics show cumulative count of Article Views (full-text article views including HTML views, PDF and ePub downloads, according to the available data) and Abstracts Views on Vision4Press platform.

Data correspond to usage on the plateform after 2015. The current usage metrics is available 48-96 hours after online publication and is updated daily on week days.

Initial download of the metrics may take a while.