1. P. J. M. Monteiro, P. R. L. Helene, and S. H. Kang, "Designing Concrete Mixtures for Strength, Elastic Modulus and Fracture Energy", Materials and Structures, Vol.26, pp.443~452, 1993.
2. A. M. Neville, "Aggregate Bond and Modulus of Elastic of Concrete", ACI Material Journal, Vol.94, No.1, pp.71~74, 1997.
3. F. A. Oluokun, E. G. Burdette, and J. H. Deatherage, "Elastic Modulus, Poisson's Ratio, and Compressive Strength Relationships at Early Ages", ACI Material Journal, Vol.88, No.1, pp.3~10, 1991.
4. P. K. Mehta, P. J. M. Monteiro, "Concrete-structure, properties, and materials", Prentice Hall, pp.117~121, pp.404~416, pp.2445~250, 1993.
5. W. F. Chen, J. E. Dahl, "Polymer-Impregnated Concrete as a Structural Material", Magazine for Concrete Research, Vol.26, No.86, pp.16~20, 1974.
6. J. Cook, "Research and Application of High Strength Concrete Using Class C Fly Ash", Concrete International, Design and Construction, Vol.4, No.7, pp.72~80, 1982.
7. P. S. Mangat, and B. T. Molloy, "Influence of PFA, Slag and Microsilica on Chloride Induced Corrosion of Reinforced in Concrete", Cement and Concrete Research, Vol.21, No.5, pp.819~834, 1991.
8. A. Bilodeau, V. Sivasundaram, K. E. Painter, and V. M. Malhotra, "Durability of Concrete Incorporating High Volumes of Fly Ash from Sources in the U.S.", ACI Materials Journal, Vol.91, No.1, pp.3~12, 1994.
9. Z. M. El-Shakra and V. S. Gopalaratnam, "Deflection Measurements and Toughness Evaluations for FRC", Cement and Concrete Research, Vol.23, pp.1455~1466, 1993.
10. P. Balaguru, R. Narahari, and M. Patel, "Flexural Toughness of Steel Fiber Reinforced Concrete", ACI Materials Journal, Vol.89, No.6, pp.541~546, 1992.
11. G. Chanvillard, N. Banhia, and P. -C. Aitcin, "Normalized Load-Deflection Curves for Fibre Reinforced Concrete under Flexure", Cement & Concrete Composites, Vol.12, pp.41~45, 1990.
12. ASTM C311, "Standard Test Methods for Sampling and Testing Fly Ash or Natural Pozzolans for Use as a Mineral Admixture in Portland-Cement Concrete", 1990.
13. R.O. Lane, "Effects of Fly Ash on Freshly Mixed Concrete", Concrete International, October, pp.50~52, 1983.
14. D. Ravina, P. K. Mehta, "Properties of Fresh Concrete Containing Large Amounts of Fly Ash", Cement and Concrete Research, Vol.16, No.2, pp.227~238, 1986.
15. P. K. Mehta, "Influence of Fly Ash Characteristics on the Strength of Portland-Fly Ash Mixtures", Cement Concrete Research, Vol.15, No.4, pp.669~674, 1985.
16. 黃兆龍, 郭淑德, 劉昌民, "含飛灰及強塑劑對水泥水化機理與性質之研究", 臺電工程月刊, 第528期, pp.44~64, 81年8月.
17. 林平全, "飛灰混凝土", 科技圖書股份有限公司, 第四版, pp.45~53, 84年12月.
18. C. L. Hwang and D. H. Shen, "The Effects of Blast-Furnace Slag and Fly Ash on the Hydration of Portland Cement", Cement and Concrete Research, Vol.21, No.4, pp.410-425, 1991.
19. T. R. Naik and S. S. Singh, "Influence of Fly Ash on Setting and Hardening Characteristics of Concrete Systems", ACI Materials Journal, Vol.94, No.5, pp355~360, 1997.
20. D. Ravina, "Slump Retention of Fly Ash Concrete With and Without Chemical Admixtures", Concrete International, April, pp.25~29, 1995.
21. D. Ravina, "Slump Loss of Fly Ash Concrete", Concrete International, April, pp.35~39, 1984.
22. D. Ravina, P. K. Mehta, "Compressive Strength of Low/High Fly Ash Concrete", Cement and Concrete Research, Vol.18, No.4, pp.571~583, 1988.
23. T. R. Naik, S. S. Singh, and M. M. Hossain, "Enhancement in Mechanical Properties of Concrete Due to Blended Ash", Cement and Concrete Research, Vol.26, No.1, pp.49~54, 1996.
24. 林炳炎, "飛灰用在混凝土中", 現代營建雜誌社, 初版, pp.162, 80年5月.25. M. G. Alexander and T. I. Milne, "Influence of Cement Blend and Aggregate Type on Stress-Strain Behavior and Elastic Modulus of Concrete", ACI Materials Journal, Vol.92, No.3, pp.227~235, 1995.
26. F. D. Larrard and A. Belloc, "The Influence of Aggregate on the Compressive Strength of Normal and High-Strength Concrete", ACI Materials Journal, Vol.94, No.5, pp.417~426, 1997.
27. A. Cetin and R. L. Carrasquillo, "High-Performance Concrete : Influence of Coarse Aggregates on Mechanical Properties", Vol.95, No.3, pp.252~261, 1998.
28. W. Baalbaki, B. Benmokrane, O. Chaallal, and P. C. Aitcin, "Influence of Coarse Aggregate on Elastic Properties of High-Performance Concrete", ACI Materials Journal, Vol.88, No.5, pp.499~503, 1991.
29. G. Giaccio, C. Rocco, D. Violini, J. Zappitelli, and R. Zerbino, "High-Strength Concretes Incorporating Different Coarse Aggregates", ACI Materials Journal, Vol.89, No.3, pp242~246, 1992.
30. P. C. Aitcin and P. K. Mehta, "Effect of Coarse-Aggregate Characteristics on Mechanical Properties of High-Strength Concrete", ACI Materials Journal, Vol.87, No.2, pp.103~107, 1990.
31. C. C. Yang, "Effect of the Transition Zone on the Elastic Moduli of Mortar", Cement and Concrete Research, Vol.28, No.5, pp727~736, 1998.
32. P. J. Tikalsky and R. L. Carrasquillo, "Influence of Fly Ash on the Sulfate Resistance of Concrete", ACI Structural Journal, Vol.89, No.1, pp.69~75, 1992.
33. J. Olek and S. Diamond, "Proportioning of Constant Paste Composition Fly Ash Concrete Mixes", ACI Materials Journal, Vol.86, No.2, pp159~166, 1989.
34. 吳鍾瑾, "飛灰在滾壓混凝土中的作用及其影響", 土木水利, 第20卷, 第3期, pp.51~59, 82年11月.35. M. K. Gopalan, "Nucleation and Pozzolanic Factors in Strength Development of Class F Fly Ash Concrete", ACI Materials Journal, Vol.90, No.2, pp.117~121, 1993.
36. N. J. Gardner, "Effect of Temperature on the Early-Age Properties of Type I, Type III, and Type/Fly Ash Concretes", ACI Materials Journal, Vol.87, No.1, pp.68~78, 1989.
37. R. N. Swamy and H. B. Mahmud, "Mix Proportions and Strength Characteristics of Concrete Containing 50 Percent Low-Calcium Fly Ash", Fly ash, Silica Fume, Slag, and Natural Pozzolans in Concrete: proceedings, second international conference, Madrid, Spain, sp-91, pp.413~432, 1986.
38. ACI 226, "Ground Granulated Blast-Furnace Slag as a Cementitious Constituent in Concrete", ACI 226.1R-87.
39. V. M. Malhotra, "Fly Ash, Slag, Silica Fume, and Rice-Husk Ash in Concrete: A Review", Concrete International, April, pp.23~28, 1993.
40. J. W. Meusel and J. H. Rose, "Production of GBF Slag at Sparrowos Point, and the Workability and Strength Potential of Concrete Incorporating the Slag", ACI sp-79, pp.867~890, 1983.
41. V. Sivasundaram and V. M. Malhotra, "Properties of Concrete Incorporating Low Quantity of Cement and High Volumes of Ground Granulated Slag", ACI Materials Journal, Vol.89, No.6, pp.554~563, 1992.
42. S. Nishibayashi, A. Yoshino, S. Hideshima, M. Takada, and T. Chikada, "A Study on Superplasticized Concrete Containing High Volumes of Blast-Furnace Slag", Superplasticizers and other chemical admixtures in concrete: proceedings, third international conference, Ottawa, Canada, sp-119, pp.445~455, 1989.
43. P. J. Wainwright and J. J. A. Tolloczko, "Early and Later Age Properties of Temperature Cycled Slag-OPC Concretes", Fly ash, Silica Fume, Slag, and Natural Pozzolans in Concrete: proceedings, second international conference, Madrid, Spain, sp-91, pp.1293~1321, 1986.
44. D. M. Roy and G. M. Idorn, "Hydration, Structure, and Properties of Blast Furnace Slag Cements, Mortars, and Concrete", ACI Journal, Vol.26, Mar., pp.444~457, 1982.
45. J. J. Brooks and A. F. Al-Kaisi, "Early Strength Development of Portland and Slag Cement Concretes Cured at Elevated Temperatures", ACI Materials Journal, Vol.87, No.5, pp.503~507, 1990.
46. L. Jianyong and T. Pei, "Effect of Slag and Silica Fume on Mechanical Properties of High Strength Concrete", Cement and Concrete Research, Vol.27, No.6, pp833~837, 1997.
47. P. S. Mangat and J. M. Khatib, "Influence of Fly Ash, Silica Fume, and Slag on Sulfate Resistance of Concrete", ACI Materials Journal, Vol.92, No.5, pp.542~552, 1995.
48. V. M. Malhotra, "Superplasticizers, Pozzolans, and Granulated Blast-Furnace Slags in Concretes: A Review", Lewis H. Tuthill International Symposium on Concrete and Concrete Construction, sp-104, pp.63~88, 1987.
49. W. C. Jau and D. S. Tsay, "A Study of the Basic Engineering Properties of Slag Cement Concrete and Its Resistance Seawater Corrosion", Cement and Concrete Research, Vol.28, No.10, pp.1363~1371, 1998.
50. P. M. Gifford and J. E. Gillott, "Freeze-Thaw Durability of Activated Blast Furnace Slag Cement Concrete", ACI Material Journal, Vol.93, No.3, pp.242~245, 1996.
51. E. Douglas, A. Bilodeau, and V. M. Malhotra, "Properties and Durability of Alkali-Activated Slag Concrete", ACI Materials Journal, Vol.89, No.5, pp.509~516, 1992.
52. E. Douglas, A. Bilodeau, J. Brandstetr, and V. M. Malhotra, "Alkali Activated Ground Granulated Blast-Furnace Slag Concrete : Preliminary Investigation", Cement and Concrete Research, Vol.21, No.1, pp.101~108, 1991.
53. P. J. Tumidajski and G. W. Chan, "Durability of High Performance Concrete in Magnesium Brine", Cement and Concrete research, Vol.26, No.4, pp.557~565, 1996.
54. R. N. Swamy and A. Bouikni, "Some Engineering Properties of Slag Concrete as Influenced by Mix Proportioning and Curing", ACI Materials Journal, Vol.87, No.3, pp.210~220, 1990.
55. ASTM C1017, "Standard Specification for Chemical Admixtures for Use in Producing Flowing Concrete", 1992.
56. K. C. Hover, "Concrete Mixture Proportioning with Water-Reducing Admixtures to Enhance Durability: A Quantitative Model", Cement and Concrete Composites, Vol.20, pp.113~119, 1998.
57. C. Nmai and B. Violetta, "The Use of Flowing Concrete in Congested Areas", Concrete International, September, pp.53~57, 1996.
58. BS1881 Testing Concrete: Part 102, "Method for the Determination of Slump", British Standards Institution, 1983.
59. A. M. Neville, "Properties of Concrete", Longman, Fourth Edition, pp.186~200, 1995.
60. BS1881 Testing Concrete: Part 105, "Method for the Determination of Flow", British Standards Institution, 1984.
61. P. Bartos, "Fresh Concrete-properties and tests", Developments in Civil Engineering, Vol.38 (in UK), pp.111~115, 1992.
62. F. D. Larrard, "A Method for Proportioning High-Strength Concrete Mixtures", Cement and Concrete and Aggregates, CCAGDP, Vol.12, No.2, pp.47~52, 1990.
63. K. W. Nasser, "New and Simple Tester for Slump of Concrete", ACI Journal, Vol.73, No.10, pp.561~565, 1976.
64. K. W. Nasser and A. A. Al-Manaseer, "Interoperator Test Program to Determine the Reliability of the K-Slump Tester", ACI Materials Journal, May-June, pp.197~201, 1988.
65. A. A. Al-Manaseer and A. J. Albert, "Measuring the Consistency and Workability of Superplasticized Concrete", ACI Material Journal, Vol.92, No.3, pp.286~290, 1995.
66. JSCE-F503, "Method of Test for the Slump Flow of Concrete", Standards of Japan Society of Civil Engineers, 1990.
67. E. K. Schrader, "Mistakes, Misconceptions, and Controversial Issues Concerning Concrete and Concrete Repairs", Concrete International, September, pp.52~56, 1992.
68. S. Popovics, "The Slump Test is Useless-or is it? ", Concrete International, September, pp.30~33, 1994.
69. M. Mittelacher, "Re-Evaluating the Slump Test", Concrete International, October, pp.53~56, 1992.
70. G.H. Tattersall, M. Sc., C. Phys., F. Inst. P., F. I. Ceram., "Workability and Quality Control of Concrete", E&FN SPON, pp.54~73, 1991.
71. C. Hu and F. D. Larrard, "The Rheology of Fresh-Performance Concrete", Cement and Concrete Research, Vol.26, No.2, pp.283~294,1996.
72. F. D. Larrard, C. Hu, T. Sedran, J. C. Szitkar, M. Joly, F. Claux, and F. Derkx, "A New Rheometer for Soft-to Fluid Fresh Concrete", ACI Materials Journal, Vol.94, No.3, pp.234~243, 1997.
73. C. Hu and F. D. Larrard, "Rheological Testing and Modeling of Fresh High Performance Concrete", Materials and Structures, Vol.28, pp.1~7, 1995.
74. J. Murata and H. Kikukawa, "Viscosity Equation for Fresh Concrete", ACI Materials Journal, Vol.89, No.3, pp.230~237, 1992.
75. I. B. Topcu and F. Kocataskin, "A Two-Phase Composite Materials Approach to the Workability of Concrete", Cement and Concrete Composites, Vol.17, pp.319~325, 1995.
76. P. F. G. Banfill, "Experimental Investigations of the Rheology of Fresh Mortar", Properties of Fresh Concrete: Proceedings of the colloquium organized on Behalf of the Coordinating Committee for Concrete Technology of RILEM, pp.145~153, 1990.
77. J. Murata and K. Suzuki, "New Method of Testing the Flowability of Grout", Magazine of Concrete Research, Vol.49, No.181, pp.269~276, 1997.
78. H. Okamura, "Self-Compacting High-Performance Concrete", Concretge International, July, pp.50~54, 1997.
79. M. Hayakama, Y. Matsuoka, and T. Shindoh, "Development and Application of Super-Workable Concrete", Proceedings of the International RILEM Workshop Organized by RiLEM Technical Committee TC 145: Special Concretes Workability and Mixing, E&FN SPON, 1994.
80. H. Okamura and K. Ozawa, "Self-Compacting High Performance Concrete", Structural Engineering International, pp.269~270, 1996.
81. M. Ouchi, M. Hibino, and H. Okamura, "Effect of Superplasticizer on Self-Compactability of Fresh Concrete", Transportation Research Record, No.1574, pp.37~40, 1996.
82. H. Kasami, T. Ikeda, and S. Yamane, "On Workability and Pumpability of Superplasticized Concrete-Experience in Japan", Superplasticizers in concrete, sp-62, pp.67~85, 1979.
83. P. C. Aitcin, C. Jolicoeur, and G. MacGregor, "Superplasticizers: How They Work and Why They Occasionally Don't", Concrete International, May, pp.45~52, 1994.
84. A. A. Ramezanianpour, V. Sivasundaram, and V. M. Malhotra, "Superplasticizers: Their Effect on the Strength Properties of Concrete", Concrete International, April, pp.30~35, 1995.
85. S. Y. Chan, N. Q. Feng, and M. K. C. Tsang, "Workability Retention of High Strength/Superplasticized Concrete", Magazine of Concrete Research, Vol.48, No.177, pp.301~309, 1996.
86. J. Punkki, J. Golaszewski, and O. E. Gjorv, "Workability Loss of High-Strength Concrete", ACI Materials Journal, Vol.93, No.5, pp.427~431, 1996.
87. A. F. Abbasi, M. Ahmad, and M. Wasim, "Optimization of Concrete Mix Proportioning Using Reduced Factorial Experimental Technique", ACI Materials Journal, Vol.84, No.1, pp.55~63, 1987.
88. P. Domone, "The Slump Flow Test for High-Workability Concrete", Cement and Concrete Research, Vol.28, No.2, pp.177~182, 1998.