References
- Abe, T. (1999). "Result of reference review on crack width effect to carbonation of concrete", Proceedings of Symposium on Rehabilitation of Concrete Structures, 1(1), 7-14.
- CEB. (1997). New Approach to Durability Design, CEB Bulletin 238, 96-102.
- CEB-FIP. (2006). Model Code for Service Life Design, The International Federation for Structural Concrete, Task Group 5.6, 28-53.
- Ishida, T., Maekawa, K. (2001). Modeling of ph profile in pore water based on mass transport and chemical equilibrium theory, Concrete Library of JSCE, 37(6), 151-166.
- Ishida, T., Maekawa, K. (2003). "Modeling of durability performance of cementitious materials and structures based on thermo-hygro physics", RILEM Proceedings PRO 29: Life Prediction and Aging Management of Concrete Structures, 39-49.
- Izumi, I., Kita, D., Maeda, H. (1986). Carbonation, Kibodang Publication, 35-88.
- JSCE Concrete Committee. (2002). Standard Specification for Concrete Structures.
- Korea Concrete Institute. (2004). Concrete Standard Specification-Durability Part, 36-69.
- Kwon, S.J., Na, U.J. (2011). Prediction of durability for rc columns with crack and joint under carbonation based on probabilistic approach, International Journal of Concrete Structures and Materials, 5(1), 11-18. https://doi.org/10.4334/IJCSM.2011.5.1.011
- Kwon, S.J., Na, U.J., Park, S.S., Jung, S.H. (2009). Service life prediction of concrete wharves with early-aged crack: probabilistic approach for chloride diffusion, Structural Safety, 31(1), 75-83. https://doi.org/10.1016/j.strusafe.2008.03.004
- Kwon, S.J., Park, S.S. (2007). A study on estimation for chloride diffusivity in cracked concrete in harbor structures through field survey, Journal of the Korean Society of Civil Engineers, 27(5A), 745-752 [in Korean].
- Kwon, S.J., Park, S.S., Nam, S.H., Cho, H.J. (2007). A study on survey of carbonation for sound, cracked, and joint concrete in rc column in metropolitan city, Journal of Korea Structure Maintenance Institute, 11(3), 116-122 [in Korean].
- Kwon, S.J., Song, H.W. (2010). Analysis of carbonation behavior in concrete using neural network algorithm and carbonation modeling, Cement and Concrete Research, 40(1), 119-127. https://doi.org/10.1016/j.cemconres.2009.08.022
- Maekawa, K., Ishida, T., Kishi, T. (2009). Multi-scale Modeling of Structural Concrete, Taylor&Francis, 86-105.
- Papadakis, V.G., Vagenas, C.G., Fardis, M.N. (1991). Physical and chemical characteristics affecting the durability of concrete, ACI Materials Journal, 88(2), 186-196.
- RILEM. (1994). Durability Design of Concrete Structures, Report of RILEM Technical Committee 130-CSL, E&FN, 28-52.
- Saeki, T., Ohga, H., Nagataki, S. (1990). Change in microstructure of concrete due to carbonation, Concrete Library of JSCE, 18(12), 1-11.
- Song, H.W., Kwon, S.J. (2007). Permeability characteristics of carbonated concrete considering capillary pore structure, Cement and Concrete Research, 37(6), 909-915. https://doi.org/10.1016/j.cemconres.2007.03.011
- Song, H.W., Kwon, S.J., Byun, K.J., Park, C.K. (2006). Predicting carbonation in early-aged cracked concrete, Cement and Concrete Research, 36(5), 979-989. https://doi.org/10.1016/j.cemconres.2005.12.019
- Sudret, B., Defaux, G., Pendola, M. (2005). Time-variant finite element reliability analysis-application to the durability of cooling towers, Structural Safety, 27(2), 93-112. https://doi.org/10.1016/j.strusafe.2004.05.001