Effect of micro-climate variations on carbonation rate of concrete in the inland environment

Yunusa Aminu Alhassan; Sunday Apeh

doi:10.1051/matecconf/201928902001

All issues

Volume 289 (2019)

MATEC Web Conf., 289 (2019) 02001

References

Open Access

Issue		MATEC Web Conf. Volume 289, 2019 Concrete Solutions 2019 – 7^th International Conference on Concrete Repair


Article Number		02001
Number of page(s)		6
Section		Patch Repair
DOI		https://doi.org/10.1051/matecconf/201928902001
Published online		28 August 2019

L. Bertolini, B. Elsener, P. Pedeferri, E. Redaelli, R.B. Polder. Corrosion of steel in concrete: prevention, diagnosis, repair: Wiley.com. (2013). [CrossRef] [Google Scholar]
P.K. Mehta. Durability of concrete--fifty years of progress? ACI Special Publication, 126. (1991) [Google Scholar]
P. Mehta, P. Monteiro, P. Concrete: Structure, Properties, and Materials, Prentice-Hall, Englewood Cliffs, NJ, (1993). [Google Scholar]
L. Wu, G.X. Pu. Influencing factors of concrete carbonation and prediction model of carbonation depth. Technique of Seepage Control 8 (3), 10–12 (in Chinese with English abstract). (2002) [Google Scholar]
X.C. Zhou, X.C. Experimental study on the influence of mineral additive to the concrete air permeability. Shanxi Architecture 37 (10), 101–103 (in Chinese with English abstract). (2011) [Google Scholar]
Z.L. Meng, F. Zhu, H. Zhou, J.S. Qian. Carbonation and ways of preventing carbonation of high-volume fly ash concrete. Building Science Research of SiChuan 27 (3), 50–54 (in Chinese with English abstract). (2001) [Google Scholar]
Y. Zhang, L.X. Jiang. A practical mathematical model of concrete carbonation depth based on the mechanism. Industrial Construction 28 (1), 16–19 (in Chinese with English abstract). (1998). [Google Scholar]
D.T Niu, Z.P. Dong, J.X. Pu. Random model of predicting the carbonated concrete depth. Industrial Construction 29 (9), 41–45 (in Chinese with English abstract). (1999). [Google Scholar]
A. Oner, S. Akyuz. 2007. An experimental study on optimum usage of GGBS for thecompressive strength of concrete. Cement and Concrete Composites 29, 505–514. (2007). [CrossRef] [Google Scholar]
H.S. Shi, B.W. Xu, X.C. Zhou. Influence of mineral admixtures on compressive strength, gas permeability and carbonation of high performance concrete. Construction and Building Materials 23, 1980–1985. (2009) [CrossRef] [Google Scholar]
R. Siddique, J. Klaus. Influence of metakaolin on the properties of mortar and concrete: a review. Applied Clay Science 43, 392–400. (2009) [CrossRef] [Google Scholar]
E.H. Yang, Y.Z Yang, V.C. Li. Use of high volumes of fly ash to improve ECC mechanical properties and material greeniness. ACI Materials Journal 104 (6), 620–628. (2007). [Google Scholar]
D.M. Roy, P. Arjunan, M.R. Silsbee. Effect of silica fume, metakaolin, and low calcium fly ash on chemical resistance of concrete. Cement and Concrete Research 31, 1809–1813. (2001). [CrossRef] [Google Scholar]
H.W. Song, V. Saraswathy. 2006. Studies on the corrosion resistance of reinforced steel in concrete with ground granulated blast-furnace slag — an overview. Journal ofHazardous Materials B138, 226–233. (2006). [CrossRef] [Google Scholar]
F.S. Fulton. Fulton’s concrete technology, 9th Edition (Gill Owens, ed.), Cement and concrete Institute, Midrand, Johannesburg, RSA. (2009). [Google Scholar]
G. Verbeck. (1958). Carbonation of hydrated Portland cement. Cement and Concrete, 17–36. (1958). [CrossRef] [Google Scholar]
M. Richardson. Fundamentals of durable concrete, modern concrete technology: Published by Spon Press, London. (2002) [Google Scholar]
B.M. Fernandez, S. Simons, C. Hills, P. Carey. A review of accelerated carbonation technology in the treatment of cement-based materials and sequestration of CO2. Journal of Hazardous Materials, 112(3), 193–205. (2004) [CrossRef] [Google Scholar]
Da Silva, F., Helene, P., Castro-Borges, P., & Liborio, J. (2009). Sources of variations when comparing concrete carbonation results. Journal of materials in civil engineering, 21(7), 333–342. (2009). [CrossRef] [Google Scholar]
Ballim, Y. (1994). Curing and the durability of concrete. PhD Thesis, University of the Witwatersrand. [Google Scholar]
V.G. Papadakis. Effect of supplementary cementing materials on concrete resistance against carbonation and chloride ingress. Cement and Concrete Research, 30(2), 291–299. (2000) [CrossRef] [Google Scholar]
Y. Loo, M. Chin, C. Tam, K. Ong. (1994). A carbonation prediction model for accelerated carbonation testing of concrete. Magazine of Concrete Research, 46(168), 191–200. (1994). [CrossRef] [Google Scholar]
V.G. Papadakis, C.G. Vayenas, M.N. Fardis. Fundamental modelling and experimental investigation of concrete carbonation. American Concrete Institute Materials Journal. 88(4): 363–373. (1991). [Google Scholar]

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[1] L. Bertolini, B. Elsener, P. Pedeferri, E. Redaelli, R.B. Polder. Corrosion of steel in concrete: prevention, diagnosis, repair: Wiley.com. (2013). [CrossRef] [Google Scholar]

[2] P.K. Mehta. Durability of concrete--fifty years of progress? ACI Special Publication, 126. (1991) [Google Scholar]

[3] P. Mehta, P. Monteiro, P. Concrete: Structure, Properties, and Materials, Prentice-Hall, Englewood Cliffs, NJ, (1993). [Google Scholar]

[4] L. Wu, G.X. Pu. Influencing factors of concrete carbonation and prediction model of carbonation depth. Technique of Seepage Control 8 (3), 10–12 (in Chinese with English abstract). (2002) [Google Scholar]

[5] X.C. Zhou, X.C. Experimental study on the influence of mineral additive to the concrete air permeability. Shanxi Architecture 37 (10), 101–103 (in Chinese with English abstract). (2011) [Google Scholar]

[6] Z.L. Meng, F. Zhu, H. Zhou, J.S. Qian. Carbonation and ways of preventing carbonation of high-volume fly ash concrete. Building Science Research of SiChuan 27 (3), 50–54 (in Chinese with English abstract). (2001) [Google Scholar]

[7] Y. Zhang, L.X. Jiang. A practical mathematical model of concrete carbonation depth based on the mechanism. Industrial Construction 28 (1), 16–19 (in Chinese with English abstract). (1998). [Google Scholar]

[8] D.T Niu, Z.P. Dong, J.X. Pu. Random model of predicting the carbonated concrete depth. Industrial Construction 29 (9), 41–45 (in Chinese with English abstract). (1999). [Google Scholar]

[9] A. Oner, S. Akyuz. 2007. An experimental study on optimum usage of GGBS for thecompressive strength of concrete. Cement and Concrete Composites 29, 505–514. (2007). [CrossRef] [Google Scholar]

[10] H.S. Shi, B.W. Xu, X.C. Zhou. Influence of mineral admixtures on compressive strength, gas permeability and carbonation of high performance concrete. Construction and Building Materials 23, 1980–1985. (2009) [CrossRef] [Google Scholar]

[11] R. Siddique, J. Klaus. Influence of metakaolin on the properties of mortar and concrete: a review. Applied Clay Science 43, 392–400. (2009) [CrossRef] [Google Scholar]

[12] E.H. Yang, Y.Z Yang, V.C. Li. Use of high volumes of fly ash to improve ECC mechanical properties and material greeniness. ACI Materials Journal 104 (6), 620–628. (2007). [Google Scholar]

[13] D.M. Roy, P. Arjunan, M.R. Silsbee. Effect of silica fume, metakaolin, and low calcium fly ash on chemical resistance of concrete. Cement and Concrete Research 31, 1809–1813. (2001). [CrossRef] [Google Scholar]

[14] H.W. Song, V. Saraswathy. 2006. Studies on the corrosion resistance of reinforced steel in concrete with ground granulated blast-furnace slag — an overview. Journal ofHazardous Materials B138, 226–233. (2006). [CrossRef] [Google Scholar]

[15] F.S. Fulton. Fulton’s concrete technology, 9th Edition (Gill Owens, ed.), Cement and concrete Institute, Midrand, Johannesburg, RSA. (2009). [Google Scholar]

[16] G. Verbeck. (1958). Carbonation of hydrated Portland cement. Cement and Concrete, 17–36. (1958). [CrossRef] [Google Scholar]

[17] M. Richardson. Fundamentals of durable concrete, modern concrete technology: Published by Spon Press, London. (2002) [Google Scholar]

[18] B.M. Fernandez, S. Simons, C. Hills, P. Carey. A review of accelerated carbonation technology in the treatment of cement-based materials and sequestration of CO2. Journal of Hazardous Materials, 112(3), 193–205. (2004) [CrossRef] [Google Scholar]

[19] Da Silva, F., Helene, P., Castro-Borges, P., & Liborio, J. (2009). Sources of variations when comparing concrete carbonation results. Journal of materials in civil engineering, 21(7), 333–342. (2009). [CrossRef] [Google Scholar]

[20] Ballim, Y. (1994). Curing and the durability of concrete. PhD Thesis, University of the Witwatersrand. [Google Scholar]

[21] V.G. Papadakis. Effect of supplementary cementing materials on concrete resistance against carbonation and chloride ingress. Cement and Concrete Research, 30(2), 291–299. (2000) [CrossRef] [Google Scholar]

[22] Y. Loo, M. Chin, C. Tam, K. Ong. (1994). A carbonation prediction model for accelerated carbonation testing of concrete. Magazine of Concrete Research, 46(168), 191–200. (1994). [CrossRef] [Google Scholar]

[23] V.G. Papadakis, C.G. Vayenas, M.N. Fardis. Fundamental modelling and experimental investigation of concrete carbonation. American Concrete Institute Materials Journal. 88(4): 363–373. (1991). [Google Scholar]