Mobile QR Code QR CODE
Export citation EndNote

References

1 
ASTM C 597-22 (2022) Standard Test Method for Ultrasonic Pulse Velocity Through Concrete. West Conshohocken, PA: ASTM International.URL
2 
ASTM C109/C109M-21 (2021) Standard Test Method for Compressive Strength of Hydraulic Cement Mortars (Using 2-in. or [50-mm] Cube Specimens). West Conshohocken, PA: AS TM International.URL
3 
Burhan, L., Ghafor, K., and Mohammed, A. (2020) Testing and Evaluation of Flowability, Viscosity and Long-term Compressive Strength of Cement Modified with Polymeric Admixture WR Superplasticizer. IOP Conference Series: Materials Science and Engineering 737, 012066.DOI
4 
Dzuy, N. Q., and Boger, D. V. (1983) Yield Stress Measurement for Concentrated Suspensions. Journal of Rheology 27(4), 321-349.DOI
5 
Feys, D., Wallevik, J. E., Yahia, A., Khayat, K. H., and Wallevik, O. H. (2013) Extension of the Reiner-Riwlin Equation to Determine Modified Bingham Parameters Measured in Coaxial Cylinders Rheometers. Materials and Structures 46, 289-311.DOI
6 
He, Z., Shen, A., Guo, Y., Lyu, Z., Li, D., Qin, X., Zhao, M., and Wang, Z. (2019) Cement-based Materials Modified with Superabsorbent Polymers: A Review. Construction and Building Materials 225, 569-590.DOI
7 
Hong, G., and Choi, S. (2017) Rapid Self-sealing of Cracks in Cementitious Materials Incorporating Superabsorbent Polymers. Construction and Building Materials 143, 366-375.DOI
8 
Hong, G., and Choi, S. (2018) Modeling Rapid Self-sealing of Cracks in Cementitious Materials Using Superabsorbent Polymers. Construction and Building Materials 164, 570-578.DOI
9 
Hong, G., Kim, J., Oh, S., Song, C., and Choi, S. (2021a) Effect of Crack Widths and Water Pressures on Crack Sealing Behavior of Cementitious Materials Incorporating Spherical Superabsorbent Polymers. Construction and Building Materials 300, 124219.DOI
10 
Hong, G., Oh, S., Choi, S., Chin, W. J., Kim, Y. J., and Song, C. (2021b) Correlation between the Compressive Strength and Ultrasonic Pulse Velocity of Cement Mortars Blended with Silica Fume: An Analysis of Microstructure and Hydration Kinetics. Materials 14(10), 2476.DOI
11 
Hong, G., Oh, S., Kim, J., Chin, W. J., Kim, Y. J., Choi, S., and Song, C. (2022) Surface-fractal-dimension Characteristics of Cementitious Composites with Multi-walled Carbon Nanotubes Dispersed by Silica Fume. Construction and Building Materials 329, 127182.DOI
12 
Hong, G., Song, C., and Choi, S. (2020) Autogenous Healing of Early-age Cracks in Cementitious Materials by Superabsorbent Polymers. Materials 13(3), 690.DOI
13 
Hong, G., Song, C., Park, J., and Choi, S. (2019) Hysteretic Behavior of Rapid Self-sealing of Cracks in Cementitious Materials Incorporating Superabsorbent Polymers. Construction and Building Materials 195, 187-197.DOI
14 
Hwang, J. W., Yang, K. H., Yoon, H. S., and Lee, S. S. (2022) Feasibility Tests of Bacteria-Based Self-Healing Pellets to Repair Mortar Cracks. Journal of the Korea Concrete Institute 34(5), 487-496.DOI
15 
Justs, J., Wyrzykowski, M., Bajare, D., and Lura, P. (2015) Internal Curing by Superabsorbent Polymers in Ultra-high Performance Concrete. Cement and Concrete Research 76, 82-90.DOI
16 
Kang, S. H., Moon, J., and Hong, S. G. (2016) Effect of Internal Curing by Super-absorbent Polymer (SAP) on Hydration, Autogenous Shrinkage, Durability and Mechanical Characteristics of Ultra-high Performance Concrete (UHPC). Journal of the Korea Concrete Institute 28(3), 317-328. (In Korean)DOI
17 
KATS (2022) Cement-Test Methods-Determination of Strength (KS L ISO679 4009). Seoul, Korea: Korea Agency for Technology and Standards (KATS), Korea Standard Association (KSA). 1-32. (In Korean)URL
18 
Koehler, E. P., and Fowler, D. W. (2004) Development of a Portable Rheometer for Fresh Portland Cement Concrete. USA, Texas: Aggregates Foundation for Technology, Research, and Education. No. ICAR 105-3FURL
19 
Kong, X. M., Zhang, Z. L., and Lu, Z. C. (2015) Effect of Pre-soaked Superabsorbent Polymer on Shrinkage of High- strength Concrete. Materials and Structures 48, 2741-2758.DOI
20 
Lee, S. H., Kim, H. J., Lim, Y. J., Kim, D. H., and Park, B. S. (2019) Effect of Na2SO4 on Autogenous Healing in Initial Cracking of Blast Furnace Slag Cement Paste. Journal of the Korea Concrete Institute 31(3), 261-267.DOI
21 
Lura, P. (2003) Autogenous Deformation and Internal Curing of Concrete. Ph.D Thesis. Delft University of Technology.URL
22 
Mehta, P. K., and Monteiro, P. J. (2006) Concrete: Microstructure, Properties, and Materials. 3rd Editon. USA, New York: McGraw Hill Higher Education.URL
23 
Oh, S., and Choi, S. (2023) Effects of Superabsorbent Polymers (SAP) on the Rheological Behavior of Cement Mortars: A Rheological Study on Performance Requirements for 3D Printable Cementitious Materials. Construction and Building Materials 392, 131856.DOI
24 
Oh, S., Hong, G., and Choi, S. (2023) Determining the Effect of Superabsorbent Polymers, Macrofibers, and Resting Time on the Rheological Properties of Cement Mortar Using Analysis of Variance (ANOVA): A 3D Printing Perspective. Journal of Building Engineering 75, 106967.DOI
25 
Snoeck, D., Schaubroeck, D., Dubruel, P., and De Belie, N. (2014) Effect of High Amounts of Superabsorbent Polymers and Additional Water on the Workability, Microstructure and Strength of Mortars with a Water-to-Cement ratio of 0.50. Construction and Building Materials 72, 148-157.DOI
26 
Snoeck, D., Schröfl, C., and Mechtcherine, V. (2018) Recommendation of RILEM TC 260-RSC: Testing Sorption by Superabsorbent Polymers (SAP) Prior to Implementation in Cement-based Materials. Materials and Structures 51(5), 116.DOI
27 
Wu, L., Farzadnia, N., Shi, C., Zhang, Z., and Wang, H. (2017) Autogenous Shrinkage of High Performance Concrete: A Review. Construction and Building Materials 149, 62-75.DOI
28 
Zhang, Q., Zeng, Q., Zheng, D. C., Wang, J., and Xu, S. L. (2018) Oven Dying Kinetics and Status of Cement-based Porous Materials for In-lab Microstructure Investigation. Advances in Cement Research 30(5), 204-215.DOI