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Journal of the Korea Concrete Institute

ISO Journal TitleJ Korea Concr Inst.
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  • KCI Accredited Journal

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  3. 2018-06 (Vol.30 No.3)
  4. 10.4334/JKCI.2018.30.3.315
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1 
Altan, E. and Erdoğan, S. T. (2012) Alkali Activation of a Slag at Ambient and Elevated Temperatures, Cement & Concrete Com--posites 34, 131-139.DOI
2 
Atiş, C. D., Bilim, C., Ҫelik, Ӧ., and Karahan, O. (2009) Influence of Activator on the Strength and Drying Shrinkage of Alkali- activated Slag Mortar, Construction and Building Materials 23, 548-555.DOI
3 
Aydın, S. and Baradan, B. (2012) Mechanical and Microstru-ctural Properties of Heat Cured Alkali-activated Slag Mortars, Materials and Design 35, 374-383.DOI
4 
Bellmann, F. and Stark, J. (2009) Activation of Blast Furnace Slag by a New Method, Cement and Concrete Research 39, 644- 650.DOI
5 
Bernal, S. A. and Provis, J. L. (2014) Durability of Alkali-activated Materials: Progress and Perspectives, Journal of American Ceramic Society 97, 997-1008.DOI
6 
Bernal, S. A., Gutierrez,R. M., Provis, J. L., and Rose, V. (2010) Effect of Silicate Modulus and Metakaolin Incorporation on the Carbonation of Alkali Silicate-activated Slags, Cement and Con-crete Research 40, 898-907.DOI
7 
Bonaccorsi, E. and Merlino, S. (2005) The Crystal Structure of Tobermorite 14Å (Plombierite) a C-S-H Phase, Journal of American Ceramic Society 88, 505-512.DOI
8 
Brough, A. R. and Atkinson, A. (2002) Sodium Silicate-based, Alkali-activated Slag Mortars Part I. Strength, Hydration and Microstructure, Cement and Concrete Research 32, 865-879.DOI
9 
Burciaga-Díaz, O. and Escalante-García, J. I. (2013) Structure, Mechanisms of Reaction, and Strength of an Alkali-activated Blast-furnace Slag, Journal of American Ceramic Society 96, 3939-3948.DOI
10 
Caijun S., Pavel V. K., and Della R. (2006) Alkali-Activated Ce-ments and Concrtes, Taylor & Francis.Google Search
11 
Chang, J. J., Yeih, W., and Hung, C. C. (2005) Effects of Gypsum and Phosphoric Acid on the Properties of Sodium Silicate- based Alkali-activated Slag Pastes, Cement & Concrete Com-po--sites 27, 85-91.DOI
12 
Chi, M. (2012) Effects of Dosage of Alkali-activated Solution and Curing Conditions on the Properties and Durability of Alkali- activated Slag Concrete, Construction and Building Mate-rials 35, 240-245.DOI
13 
Collins, F. and Sanjayan, J. G. (2000) Effect of Pore Size Distri-bution on Drying Shrinkage of Alkali-activated Slag Concrete, Cement and Concrete Research 30, 1401-1406.DOI
14 
Escalante-García, J. I., Fuentes, A. F., Gorokhovsky, A., Fraire- Luna, P. E., and Mendoza-Suarez, G. (2003) Hydration Pro-ducts and Reactivity of Blast-furnace Slag Activated by Various Alkalis, Journal of American Ceramic Society 86, 2148-2153.DOI
15 
Escalante-Garcia, J. I., Palacios-Villanueva, V. M., Gorokhovsky, A. V., Mendoza-Suárez, G., and Fuentes, A. F. (2002) Cha-rac--teristics of a NaOH-activated Blast Furnace Slag Blended with a Fine Particle Silica Waste, Journal of American Cera-mic Society 85, 1788-1792.DOI
16 
Fernánadez-Jiménez, A. and Puertas, F. (2002) The Alkali-silica Reaction in Alkali-activated Granulated Slag Mortars with Rea-c--tive Aggregate, Cement and Concrete Research 32, 1019- 1024.DOI
17 
Fernánadez-Jiménez, A. and Puertas, F. (2003) Structure of Calcium Silicate Hydrates Formed in Alkaline-activated Slag: Influence of the Type of Alkaline Activator, Journal of Ame-rican Ceramic Society 86, 1389-1394.DOI
18 
Fernández-Jiménez, A., Palomo, J. G., and Puertas, F. (1999) Alkali-activated Slag Mortars Mechanical Strength Beha-viour, Cement and Concrete Research 29, 1313-1321.DOI
19 
Haha, M. B., Lothenbach, B., Le Saout, G., and Winnefeld, F. (2011) Influence of Slag Chemistry on the Hydration of Alkali-activated Blast-furnace Slag – Part I: Effect of MgO, Cement and Concrete Research 41, 955-963.DOI
20 
Haha, M. B., Lothenbach, B., Le Saout, G., and Winnefeld, F. (2012) Influence of Slag Chemistry on the Hydration of Alkali-activated Blast-furnace Slag – Part II: Effect of Al2O3, Ce-ment and Concrete Research 42, 74-83.DOI
21 
Jennings, H. M. (2000) A Model for the Microstructure of Cal-cium Silicate Hydrate in Cement Paste, Cement and Con-crete Research 30, 101-116.DOI
22 
Lecomte, I., Henrist, C., Liégeois, M., Maseri, F., Rulmont, A., and Cloots, R. (2006) (Micro)-structural Comparison between Geopolymers, Alkali-activated Slag Cement and Portland Cement, Journal of the European Ceramic Society 26, 3789- 3797.DOI
23 
Mascolo, G. and Marino, O. (1980) A New Synthesis and Characterization of Magnesium-aluminium Hydroxides, Mineralogical Magazine 43, 619-621.DOI
24 
Myers, R. J., Bernal, S. A., Gehman, J. D., Deventer, J. S. J., and Provis, J. L. (2015) The Role of Al in Cross-linking of Alkali- activated Slag Cements, Journal of the American Ceramic Society 98, 996-1004.DOI
25 
Nadoushan, M. J. and Ramezanianpour, A. A. (2016) The effect of Type and Concentration of Activators on Flowability and Compressive Strength of Natural Pozzolan and Slag-based Geopolymers, Construction and Building Materials 111, 337-347.DOI
26 
Neto, A. A. M., Cincotto, M. A., and Repette, W. (2008) Drying and Autoshrinkage of Pastes and Mortars with Activated Slag Cement, Cement and Concrete Research 38, 565-574.DOI
27 
Pacheco-Torgal, F., Castro-Gomes, J., and Jalali, S. (2008a) Alkali-activated Binders: A Review. Part 1. Historical Background, Terminology, Reaction Mechanisms and Hydra-tion Products, Construction and Building Materials 22, 1305-1314.DOI
28 
Pacheco-Torgal, F., Castro-Gomes, J., and Jalali, S. (2008b) Alkali-activated Binders: A Review. Part 2. About Materials and Binders Manufacture, Construction and Building Mate-rials 22, 1315-1322.DOI
29 
Palacios, M. and Puertas, F. (2006) Effect of Carbonation on Alkali-activated Slag Paste, Journal of American Ceramic So-ciety 89, 3211-3221.DOI
30 
Provis J. L., Palomo, A., and Shi, C. (2015) Advances in Under-s-tanding Alkali-activated Materials, Cement and Concrete Research 78, 110-125.DOI
31 
Puertas, F., Fernández-Jiménez, A., and Blanco-Varela, M. T. (2004) Pore Solution in Alkali-activated Slag Cement Pastes. Relation to the Composition and Structure of Calcium Sili-cate Hydrate, Cement and Concrete Research 34, 139-148.DOI
32 
Puertas, F., Palacios, M., Manzano, H., Dolado, J. S., Rico, A., and Rodríguez, J. (2011) A Model for the C-A-S-H Gel Formed in Alkali-activated Slag Cements, Journal of the European Ceramic Society 31, 2043-2056.DOI
33 
Rashad, A. M. (2013) A Comprehensive Overview About the Influence of Different Additives on the Properties of Alkali- activated Slag – A Guide for Civil Engineer, Con-struction and Building Materials 47, 29-55.DOI
34 
Rashad, A. M., Zeedan, S. R., and Hassan, A. A. (2016) Influence of the Activator Concentrayion of Sodium Silicate on the Thermal Properties of Alkali-activated Slag Pastes, Con-struc-tion and Building Materials 102, 811-820.DOI
35 
Rashad, A. M., Zeedan, S. R., and Hassan, H. A. (2012) A Preli-minary Study of Autoclaved Alkali-activated Slag Blended with Quartz Powder, Construction and Building Materials 33, 70-77.DOI
36 
Ravikumar, D. and Neithalath, N. (2012) Effects of Activator Characteristics on the Reaction Product Formation in Slag Binders Activated using Alkali Silicate Powder and NaOH, Cement & Concrete Composites 34, 809-818.DOI
37 
Richardson, I. G. (2004) Tobermorite/jennite- and Tobermorite/ calcium Hydroxise-based Models for the Structure of C-S-H: Applocability to Hardened Pastes of Tricalcium Silicate, β- dicalcium Silicate, Portland Cement, and Blends of Portland Cement with Blast-furnace Slag, Metakaolin, or Silica Fume, Cement and Concrete Research 34, 1733-1777.DOI
38 
Rinaldi, R., Sacerdoti, M., and Passaglia, E. (1990) Strätlingite: Crystal Structure, Chemistry, and a Reexamination of its Polytype Vertumnite, European Journal of Mineralogy 2, 841-850.DOI
39 
Saoût, G. L., Haha, M. B., Winnefeld, F., and Lothenbach, B. (2011) Hydration Degree of Alkali-activated Slags: A29 Si NMR Study, Journal of American Ceramic Society 94, 4541-4547.DOI
40 
Song K. I., Lee, B. Y., Hong, G. H., Gong, M. H., and Song, J. K. (2012) Effects of Basicity on the Carbonation Charac-te-ristics of Alkali-activated Slag Mortar, Journal of the Korea Concrete Institute 24(5), 557-584. (In Korean)DOI
41 
Walkely, B., Nicolas, R. S., Sani, M.-A., Rees, G. J., Hanna, J. V., Deventer, J. S. J., and Provis, J. L. (2016) Phase Evo-lution of C-(N)-A-S-H/N-A-S-H Gel Blends Investigated Via Alkali-activation of Synthetic Calcium Aluminosilicate Precursors, Cement and Concrete Research 89, 120-135.DOI
42 
Yang, K. H., Cho, A. R., Song, J. K., and Nam, S. H. (2012) Hydration Products and Strength Development of Calcium Hydroxide-based Alkali-activated Slag Mortars, Construc-tion and Building Materials 29, 410-419.DOI
43 
Zhang, Z., Li, L., Ma, X., and Wang, H. (2016) Compositional, Microstructural and Mechanical Properties of Ambient Condition Cured Alkali-activated Cement, Construction and Building Materials 113, 237-245.DOI
44 
Živica, V. (2007) Effects of Type and Dosage of Alkaline Activator and Temperature on the Properties of Alkali-activated Slag Mixtures, Construction and Building Materials 21, 1463- 1469.DOI