References
- Ahmed, A., K. Ugai, and T. Kamei, 2011. Investigation of recycled gypsum in conjunction with waste plastic trays for ground improvement. Construction and Building Materials 25: 208-217. https://doi.org/10.1016/j.conbuildmat.2010.06.036
- Blight, G. E., 1969. Waste gypsum as an embankment material. Proc. of the Seventh International Conference on Soil Mechanics and Foundation Engineering 39-43.
- Chamberlain, E. J., I. Iskveer, and S. E. Hunsiker, 1990. Effect of freeze-thaw on the permeability and macrostructure of soils. Proceedings International Symposium on Frozen Soil Impacts on Agricultural Range and Forest Lands 145-155. Spokane, WA.
- Garg, M., A. K. Minocha, and N. Jain, 2011. Environment hazard mitigation of waste gypsum and chalk: Use in construction materials. Construction and Building Materials 25: 944-949. https://doi.org/10.1016/j.conbuildmat.2010.06.088
- Jo, B. W., Y. J. Kim, and E. M. Hwang, 2000. The study on the development of construction materials with chemical by-product gypsum. Proc. of the Korean Concrete Institute Conference 351-354 (in Korean).
- Kellsen, K. O., 1996. Heat curing and post-heat curing regimes of high-performance concrete: influence on microstructure and C-S-H composition. Cement and Concrete Research 26(2): 295-307. https://doi.org/10.1016/0008-8846(95)00202-2
- Kim, Y. I., and Y. S. Kim, 2010. Unconfined compressive strength and micro-structure properties of CSG materials due to specimen size. Journal of the Korean Society of Agricultural Engineers 52(4): 93-101 (in Korean). https://doi.org/10.5389/KSAE.2010.52.4.093
- Kim, Y. S., D. E. Suh, W. B. Kim, and W. B. Lee, 2009. Engineering characteristics of the light weight soil using phosphogypsum and EPS beads. Journal of the Korean Geo-Environmental Society 10(6): 19-25.
- Kim, W. B., 2010. Geotechnical characterization of artificial aggregate made from phosphogymsum as a drainage material. Thesis for the Degree of Master, Gwangju: Chonnam National University.
- Koo, J. W., 1984. A Laboratory study for reclamation of salt-affected soils by gypsum amendment and water management practices. Journal of the Korean Society of Agricultural Engineers 26(2): 85-96 (in Korean).
- Lee, Y. S., H. S. Chung, and H. I. Chung, 2001. The engineering and environmental properties for utilization of phosphogypsum as embankment materials. Journal of the Korean Geotechnical Society 17(4): 331-339 (in Korean).
- Mun, K. J., W. K. Hyoung, W. C. Park, S. Y. So, and Y. S. Soh, 2006. The strength properties of cement matrix containing high-volume wasted phosphogypsum with binder types. Proc. of the Korean Concrete Institute Conference 881-884 (in Korean).
- Oh, Y. I., K. I. Kim, and E. C. Shin, 2001. Geotechnical characteristics and environmental effect of reclaimed land by utilizing waste gypsum. The KSCE Journal of Civil Engineering 21(1C): 19-26 (in Korean).
- Pericleous, M. I., and J. B. Metcalf, 1996. Resilient modulus in civil engineering. Journal of Materials in Civil Engineering 8(1): 7-10. https://doi.org/10.1061/(ASCE)0899-1561(1996)8:1(7)
- Petrukhin, V. P., 1994, Gypsum and Saline Soils. Proc. of the Thirteenth International Conference on Soil Mechanics and Foundation Engineering 265-266.
- Taha, R., 1989. Utilization of by-product gypsum in road construction. Doctor of Philosophy Dissertation, Texas A&M University.
- Wrench, B. P., and G. E. Blight, 1985. Compressibility of neutralized phosphogypsum. Proc. of the Eleventh International Conference on Soil Mechanics and Foundation Engineering 3: 1321-1326.
Cited by
- A Characteristic on Difference of Water Content with Temperature and Compaction of Gypsum to Utilize Fill Material vol.54, pp.3, 2012, https://doi.org/10.5389/KSAE.2012.54.3.047