REFERENCES - Shodhganga : a reservoir of Indian theses...

213

REFERENCES

1. Aarre T, Domone PLJ. Testing-SCC: Summary report on work package 2:

Development of mix designs and material selection. 2004.

2. AASHTO LRFD Bridge Design Specifications. 3rd edition. American

Association of Highway and Transportation Officials, Washington, D.C. 2004.

3. AASHTO LRFD Bridge Design Specifications. American Association of

Highway and Transportation Officials, Washington, D.C. 2006.

4. ACI 209R. Prediction of Creep, Shrinkage, and Temperature Effects in Concrete

Structures, ACI 209R-92. American Concrete Institute, Farmington Hills, Mich.,

1997.

5. ACI 301. Specifications for Structural Concrete. 2010.

6. ACI 237R-07. Self-Consolidating Concrete. 2007.

7. ACI 318-95. Building code requirements for structural concrete. Detroit. 1995.

8. ACI 363R. State-of-the-art report on high-strength concrete. American

Concrete Institute, Detroit. 1992.

9. Aiad I. Influence of time addition of superplasticizers on the rheological

properties of fresh cement pastes. Cement and Concrete Research, Vol. 33,

No. 8, 2003, pp1229-1234.

10. ASTM C157/C157M-08 Standard Test Method for Length Change of Hardened

Hydraulic-Cement Mortar and Concrete. ASTM International, West

Conshohocken, PA, 2008.

11. ASTM C 618. Standard specification for coal fly ash and raw or calcined natural

pozzolan for use in concrete. 2003.

214

12. Atis CD. High-volume fly ash concrete with high strength and low drying

shrinkage. Journal of Materials in Civil Engineering, Vol. 15, No. 2, 2003,

pp153-156.

13. Ayano T, Wittman FH. Drying, moisture distribution, and shrinkage of cement

based materials. Mater Struct, Vol. 35, No. 237, 2002, pp134-40.

14. Ahmaruzzaman M. A review on the utilization of fly ash”, Progress in Energy

and Combustion Science J., Vol. 36, No. 3, 2010, pp327–363.

15. Bapat SG, Kulkarni SB, Bandekar KS. Using SCC in Nuclear power plants –

Laboratory and Mock-up Trials at Kaiga. Indian Concrete Journal, Vol. 78,

No. 6, 2004, pp51-57.

16. Bazant Z, Baweja S. Creep and shrinkage prediction model for analysis and

design of concrete structures. The Adam Neville Symposium: Creep and

Shrinkage-Structural Design Effects, SP-194, American Concrete Institute,

2000, pp1-100.

17. Bentz DP, Stutzman PE. Evolution of porosity and calcium hydroxide in

laboratory concretes containing silica fume, Cement Concrete Research,

Vol. 24, 1994, pp1044–1050.

18. Bernabeu O. Productivity and Economy. In final report of Task 8.6:

Brite-EuRam Programme: BE96-3801/BRPR-CT-96-0366. Rev. No. 1. 2000.

19. Bissonnette B, Pierre P, Pigeon M. Influence of key parameters on drying

shrinkage of cementitious materials. Cem Concr Res, Vol. 25, No. 5, 1999,

pp1075–85.

20. Bijen JM, De Rooij M. Aggregate – Matrix Interfaces, International Conference

on Concretes, Dundee, Scotland, 1999.

215

21. Bonen D, Shah S. The Effects of Formulation on the Properties of Self-

Consolidating Concrete. Concrete Science and Engineering: A Tribute to Amon

Bentur, Proceedings of the International RILEM Symposium, K. Kovler, J.

Marchand, S. Mindress and J. Weiss, eds, RILEM Publications, France. 2004,

pp43-56.

22. Bouzoubaa N, Lachemi M. Self-Compacting Concrete Incorporating High

Volumes of Class F Fly Ash: Preliminary Results”. Cement and Concrete

Research, Vol. 31, 2001, pp413-420.

23. Bui VK, Montgomery D, Hinczak I, Turner K. Rapid testing method for

segregation resistance of self-compacting concrete. Cement and Concrete

Research, Vol. 32, No. 9, 2002b, pp1489-1496.

24. Campbell-Allen D, Roper H. Concrete Structures: Materials, Maintenance and

Repair. New York: Longman Scientific & Technical. Wiley. 1991.

25. Carlsward J, Emborg M, Utsi S, Oberg P. Effects of constituents on the

workability and rheology of self-compacting concrete. In: The 3rd International

RILEM Symposium on Self-Compacting Concrete. Wallevik OH, Nielsson I,

editors, RILEM Publications S.A.R.L, Bagneux, France. 2003, pp143-153.

26. CEB-FIP. Model Code for Concrete Structures 1990.

27. Cetin A, Carrasquillo RL. High-performance concrete: influence of coarse

aggregates on mechanical properties. ACI Mater. J., Vol. 95, No. 3, 1998,

pp252-

28. Chatterjee A.K. Indian Fly Ashes, Their Characteristics, and Potential for

Mechano- Chemical Activation for Enhanced Usability. Coventry University

and The University of Wisconsin Milwaukee Center for By-products Utilization,

216

Second International Conference on Sustainable Construction Materials and

Technologies, Ancona, Italy, June 28-June 30, 2010.

29. Chi JM, Huang R, Yang CC, Chang JJ. Effect of aggregate properties on the

strength and stiffness of lightweight concrete. Cement & Concrete Composites,

Vol. 25, No. 2, 2003, pp197-205.

30. Cheng AS, Huang CH, Yen T, Luo YN. Influences of Slag and Fly Ash on the

Microstructure Property and Compressive Strength of Concrete, Advn Mat Res,

Vol. 146-147, 2011, pp1690-1697.

31. Chopin D, De Larrard CF, Cazacliu B. Why do HPC and SCC require a longer

mixing time? Cement and Concrete Research,Vol. 34, No. 12, 2004,

pp2237-2243.

32. Collepardi M. Admixtures used to enhance placing characteristics of concrete.

Cement and Concrete Composites, Vol. 20, No. 2-3, 1998, pp103-112.

33. Collepardi M, Borsoi A, Collepardi S, Troli R. Strength, shrinkage and creep of

SCC and flowing concrete. In: The 2nd North American Conference on the

Design and Use of Self-consolidating Concrete and the 4th International RILEM

Symposium on Self-compacting Concrete. Shan SP, editor, A Hanley Wood

Publication, U.S.A. 2005, pp 911-920.

34. Concrete: Technical Bulletin TB – 1500. An Introduction to Self-Consolidating

Concrete (SCC). GRACE Construction Products. 2005.

35. Coppola L. Durability of Self-Compacting Concrete, Proceedings of Two-day

Seminar on Sustainable Development in Cement and Concrete Industries, Milan,

October 2003, 261-272.

36. Coppola L, Cerulli T, Salvioni D. Sustainable development and durability of

self-compacting concrete, Proceedings of the Eighth CANMET/ACI

217

International Conference on Fly Ash, Silica Fume, Slag and Natural Pozzolans

in Concrete, ACI SP-221, V.M. Malhotra, ed., American Concrete Institute,

Farmington Hills, Michigan, USA, 2004, pp29-50.

37. Cordoba B. Creep and Shrinkage of Self-Consolidating Concrete (SCC), MSc

Thesis, University of Wyoming, 2007.

38. Corradi M, Khurana R, Magarotto R. User Friendly Self-Compacting Concrete

in Precast Production. 3rd International RILEM Symposium on self-compacting

concrete, Reykjavik, Iceland. 2003, pp457-466.

39. Cussigh F, Bonnard V. Summary report of work package 3.3: Tests for

resistance to segregation. 2004.

40. Daczko J. A, Kurtz M. A. Development of High-Volume Coarse Aggregate

Self-Compacting Concrete, Proceedings of the Second International Symposium

on SCC, Oct. 23-25, Tokyo, Japan. 2001.

41. D'Ambrosia MD, Lange DA, Brinks AJ. Restrained shrinkage and creep of self-

consolidating concrete. Proc. of the Second North American Conf. on the Des.

and Use of Self Consolidating Concr. and the Fourth Int. RILEM Symp. On

Self-Consolidating Concr., Center for Advanced Cement-Based Materials

(ACBM), Chicago. 2005, pp921-928.

42. Dehn F, Holschemacher K, Weibe D. Self-compacting concrete (SCC) time

development of the material properties and the bond behaviour. LACER, Vol. 5,

2000, pp115-124.

43. De Schutter G, Audenaert K. Durability of self-compacting concrete. RILEM

report 38. Bagneux, France: RILEM Publications S.A.R.L, 2007.

44. De Schutter G, Bartos PJM, Domone PLJ, Gibbs JC. Self-compacting concrete.

Whittles Publishing. 2008.

218

45. Diamond S, Huang J. The interfacial transition zone: reality or myth? In: Katz

A, Bentur A, Alexander M, Arliguie G, editors. The interfacial transition zone in

cementitious composites. London: E. & F.N. Spoon, 1998, pp1–37.

46. Domone PLJ. Mortar tests for material selection and mix design of SCC.

Concrete International. 2006a.

47. Domone PLJ. Self-compacting concrete: An analysis of 11 years of case studies.

Cement and Concrete Composites, Vol. 28, No. 2, 2006b, pp197-208.

48. Edamatsu Y, Nishida N, Ouchi M. A rational mix-design method for

selfcompacting concrete considering interaction between coarse aggregate and

mortar particles. In: The 1st International RILEM Symposium on

Selfcompacting Concrete. Skarendahl A, Petersson O, editors, RILEM

Publications S.A.R.L., 1999, pp309-320.

49. EFNARC. Specification and guidelines for self-compacting concrete. European

Federation of Producers and Applicators of Specialist Products for Structures.

2002.

50. EFNARC. The SCC European Project Group. The European guidelines for self

compacting concrete: specification, production and use. 2005.

51. EFNARC. Guidelines for viscosity modifying admixtures for concrete. 2006.

52. Elsharief A, Cohen MD, Olek J. Influence of aggregate size, water cement ratio

and age on the microstructure of the interfacial transition zone. Cem Concr Res,

Vol. 33, 2003, pp1837-1849.

53. Emborg M. Final report of task 8.1 Mixing and transport. 2000.

54. Eureqa Formulize. Scientific data mining software package. Online available

<http://www.nutonian.com/download>.

219

55. Felekoglu B, Sarikahya H. Effect of chemical structure of polycarboxylate-

based superplasticizers on workability retention of self compacting concrete.

Construction and Building Materials, Vol. 22, No. 9, 2008, pp1972-1980.

56. Gardner NJ, Lockman MJ. Design provisions for drying shrinkage and creep of

normal-strength concrete. ACI Mater J, Vol. 98, No. 2, 2001, pp159-167.

57. Gesoglu M, Guneyisi E, Ozbay E. Properties of self-compacting concretes made

with binary, ternary, and quaternary cementitious blends of fly ash, blast furnace

slag, and silica fume. Construct Build Mater, Vol. 23, 2009, pp1847–54.

58. Gerwick, B.C. Jr. Construction of Prestressed Concrete Structures, Second

Edition, John Wiley and Sons Inc., 1993, pp591.

59. Ghazi F Kheder, Rand S Al Jaidiri. New Method for Proportioning Self-

Consolidating Concrete Based on Compressive Strength Requirements.

ACI Materials, Vol. 107, No. 5, 2010, pp490-497.

60. Ghoddousi P, Monir Abbasi A. Influence of aggregate grading and cement paste

volume on drying shrinkage of self-consolidating concrete. In: 3rd North

American conference on the design and use of self-consolidating concrete,

Chicago; 2008.

61. Grzeszczyk S, Lipowski G. Effect of content and particle size distribution of

high-calcium fly ash on the rheological properties of cement pastes, Cem Concr

Res, Vol. 27, 1997, pp907–916.

62. Guneyisi E, Gesoglu M, Ozbay E. Strength and drying shrinkage properties of

self-compacting concretes incorporating multi-system blended mineral

admixtures. Construct Build Mater, Vol. 24, 2010, pp1878-1887.

63. Halstead, W. J. Use of Fly Ash in Concrete, NCHRP Synthesis 127. 1986.

220

64. Hanehara S, Hirao H, Uchikawa H. Influence of the surface structure of

aggregates on the formation of interfacial structure between cement paste and

aggregate. J of Res of the Chichibu Onoda Cement Corporation, Vol. 47,

No. 130, 1996, pp38–43.

65. Hanehara S, Yamada K. Interaction between cement and chemical admixture

from the point of cement hydration, absorption behaviour of admixture, and

paste rheology. Cement and Concrete Research, Vol. 29, No. 8, 1999,

pp1159-1165.

66. Havlica J, Brandstetr J, Odler I. Possibilities of utilizing solid residues from

pressured fluidized bed coal combustion (PFBC) for the production of blended

cement, Cem Concr Res, Vol. 28, 1998, pp299–307.

67. Hayakawa, M., Matsuoka, Y. and Shindoh, T. Development and Application of

Super Workable Concrete, Proceedings of RILEM International Workshop on

Special Concretes: Workability and Mixing, Ed. Bartos, P.J.M., University of

Paisley. 1993, pp183-190.

68. Hearn N, Skalny J, Bajza A. Microstructures and bond in cementitious solids.

Building Research Journals, Vol. 45, No. 1, 1997, pp103-118.

69. Hewlett PC. Lea’s Chemistry of Cement and Concrete, Fourth edition, Elsevier

Ltd., 2003.

70. Holm TA. Lightweight Concrete and Aggregates, Standard Technical

Publication STP 169C. 1995, pp522-532.

71. Hsu TTC, Slate FO, Sturman GM, Winter G. Microcracking of plain concrete

and the shape of the stress–strain curve. ACIMater J, Vol. 60, No. 2, 1963,

pp209–24.

221

72. Huo XS, Al-Omaishi N., Tadros MK. Creep, Shrinkage and Modulus of

Elasticity of High-Performance Concrete. ACI Materials Journal, Vol. 98,

No. 6, 2001, pp440-449.

73. Hwang SD, Khayat KH. Effect of mixture composition on restrained shrinkage

cracking of self-consolidating concrete used in repair. ACI Mater J, Vol. 105,

No. 5, 2008, pp499–509.

74. Hwang SD, Khayat KH. Effect of mix design on restrained shrinkage of self-

consolidating concrete. Mater and Struct, Vol. 43, 2010, pp367-380.

75. IS 383. Specification for coarse and fine aggregates from natural sources for

concrete. Bureau of Indian Standards, New Delhi. 1970.

76. IS 456. Plain and reinforced concrete code for practice. Bureau of Indian

Standards, New Delhi. 2000.

77. IS 516. Methods of tests for strength of concrete. Bureau of Indian Standards,

New Delhi. 1991.

78. IS 1489 (Part 1). Portland-Pozzolana Cement Specification. Bureau of Indian


79. IS 2386. Methods of test for aggregates for concrete. Part III - Specific gravity,

Density, Voids, Absorption and Bulking. Bureau of Indian Standards, New

Delhi. 1963.

80. IS 4031. Methods of physical tests for hydraulic cement: Part 4 – Determination

of consistency of standard cement paste. Bureau of Indian Standards, New

Delhi. 1988.


of initial and final setting times. Bureau of Indian Standards, New Delhi. 1988.

222


of compressive strength of hydraulic cement (other than masonry cement).

Bureau of Indian Standards, New Delhi. 1988.

83. IS 4031. Methods of physical tests for hydraulic cement: Part 11 -

Determination of density. Bureau of Indian Standards, New Delhi. 1988.

84. IS 5816. Splitting tensile strength of concrete method of test. Bureau of Indian


85. IS 10262. Concrete Mix Proportioning-Guidelines. Bureau of Indian Standards,

New Delhi. 2009.

86. IS 12269. Specification for 53 grade ordinary Portland cement. Bureau of Indian


87. Ivanauskas E, Rudzionis Z, Navickas AA, Dauksys M. Investigation of shale

ashes influences on the self-compacting concrete properties. Mater. Sci.,

Vol. 14, No. 3, 2008, pp247–253.

88. Jin J. Properties of mortar for self-compacting concrete. University College

London. 2002.

89. Jin J, Domone PLJ. Relationships between the fresh properties of SCC and its

mortar component. In: The 1st North American Conference on the Design and

Use of Self-consolidating Concrete. Skarendahl A, editor, Chicago, USA. 2002,

pp33-38.

90. Jing HU, Stroeven P. Properties of the interfacial transition zone in model

concrete. Interface Science, Vol. 12, 2004, pp389-397.

91. Joshi, R.C. Sources of pozzolanic activity in fly ashes—a critical review. In:

Proceedings of the 5th International Fly Ash Utilization Symposium, Atlanta,

GA, USA. 1979, pp610-623.

223

92. JSCE. Japan Society of Civil Engineers. Recommendation for construction of

self-compacting concrete. 1998, pp417-437.

93. JSCE. Japan Society of Civil Engineers. Recommendation for self-compacting

concrete. JSC, Tokyo. 1999.

94. JSCE. Japan Society of Civil Engineers. Standard Specifications for Concrete

Structure. 2002.

95. Kasemchaisiri R, Tangermsirikul S. Deformability prediction model for self-

compacting concrete. Magazine of Concrete Research, Vol. 60, No. 2, 2008,

pp93-108.

96. Khatib JM. Performance of self-compacting concrete containing fly ash.

Construct Build Mater, Vol, 22, 2008, pp1963–71.

97. Khayat KH. Viscosity-enhancing admixtures for cement-based materials -

An overview. Cement and Concrete Composites, Vol. 20, No. 2-3, 1998,

pp171-188.

98. Khayat KH. Workability, testing, and performance of self-consolidating

concrete. ACI Materials Journal, Vol. 96, No. 3, 1999b, pp346-352.

99. Khayat KH, Aitcin PC. Use of self-consolidating concrete in Canada - Present

situation and perspectives. 1998, pp11-22.

100. Khayat KH, Ghezal A. Effect of viscosity modifying admixture -

superplasticizer combination on flow properties of SCC equivalent mortar. In:

The 3rd International RILEM Symposium on Self-Compacting Concrete.

Wallevik OH, Nielsson I, editors, RILEM Publications S.A.R.L., Bagneux,

France. 2003, pp369-385.

101. Khayat KH, Guizani Z. Use of viscosity-modifying admixture to enhance

stability of fluid concrete. ACI Materials, Vol. 94, No. 4, 1997, pp332-341.

224

102. Khayat K, Long WJ. Shrinkage of Precast, Prestressed Self-Consolidating

Concrete, ACI Mater J, Vol. 107, No. 3, 2010, pp231-238.

103. Khayat KH, Yahia A. Effect of welan gum-high-range water reducer

combinations on rheology of cement grout. ACI Materials Journal, Vol. 94,

No. 5, 1997, pp365-372.

104. Khurana R, Saccone R. Fly ash in self-compacting concrete, fly ash, silica fume,

slag and natural pozzolans in concrete. ACI SP, Vol. 199, 2001, pp259–274.

105. Kim JK, Ham YD, Noh JH, Park YH, Kwon YH, Lee SG. Experimental

Research on the Material Properties of Super Flowing Concrete. P. J. M. Bartos,

D. L. Marrs, and D. J. Cleland, eds., E&FN Spon, London, 1996, pp271-284.

106. Kim BG, Jiang S, Jolicoeur C, Aitcin PC. The adsorption behavior of PNS

superplasticizer and its relation to fluidity of cement paste. Cement and

Concrete Research, Vol. 30, No. 6, 2000, pp887-893.

107. Kjellsen KO, Jennings HM. Observations of microcracking in cement paste

upon drying and rewetting by environmental scanning electron microscopy.

Advn Cem Bas Mat, Vol. 3, No. 1, 1996, pp4–19.

108. Koza JR. Genetic Programming: On the Programming of Computers by Means

of Natural Selection. MIT Press, Cambridge, MA, USA. 1992.

109. Kumar V, Mathur M, Sinha SK, Dhatrak S. Fly ash: an environment saviour, in

Proc. Fly ash India, New Delhi, 2005, pp1.1–1.8.

110. Kuroda M, Watanabe T, Terashi N. Increase of bond strength at interfacial

transition zone by the use of fly ash, Cem Concr Res, Vol. 30, 2000, pp253-258.

111. Larson K. Evaluation the Time-Dependent Deformation and Bond

Characteristics of a Self-Consolidating Concrete Mix and the Implication for

Pretensioned Bridge Applications, PhD Thesis, Kansas state university, 2006.

225

112. Leemann A, Loser R, Munch B. Influence of cement type on ITZ porosity and

chloride resistance of self-compacting concrete, Cem Concr Compos, Vol. 32,

2010, pp116-120.

113. Leemann A, Lura P, Loser R. Shrinkage and creep of SCC – The influence of

paste volume and binder composition. Construct Build Mater, Vol. 15, 2011,

pp2283-2289.

114. Leemann A, Munch B, Gasser P, Holzer L. Influence of compaction on the

interfacial transition zone and the permeability of concrete, Cem Concr Res,

Vol. 36, 2006, pp1425-1433.

115. Liao KY, Chang PK, Peng YN, Yang CC. A study on characteristics of

interfacial transition zone in concrete, Cem Concr Res, Vol. 34, 2004,

pp977-989.

116. Lilkov V, Dimitrova E, Petrov OE. Hydration process of cement containing fly

ash and silica fume: The first 24 hours, Cem Concr Res, Vol. 27, 1997,

pp577–588.

117. Liniers AD. Microcracking of concrete under compression and its influence on

tensile strength. Mater Struct, Vol. 20, 1987, pp111–6.

118. Liu M. Self-compacting concrete with different levels of pulverized fuel ash.

Construction and Building Materials, Vol. 24, 2010, pp1245-1252.

119. Loser R, Leemann A. Shrinkage and restrained shrinkage cracking of self

compacting concrete compared to conventionally vibrated concrete. Mater

Struct, Vol. 42, 2009, pp:71–82.

120. Ma J, and Dietz J. Ultra high performance self compacting concrete. University

of Leipzig, Germany. 2002.

226

121. Mahdy M, Speare PRS., Abdel-Reheem AH. Mechanical Properties of Heavy

Weight, High Strength Concrete. 2nd Material Specialty Conference of the

Canadian Society for Civil Engineering, Canada. 2002, pp1-9.

122. Maso JC. The bond between aggregate and hydrated cement pastes. 7th Int.

Cong. on the Chem. of Cement, Paris, 1980.

123. Mata LA. Implementation of Self-Consolidating Concrete (SCC) for Prestressed

Concrete Girders, MS Thesis, North Carolina State University, November.

2004.

124. Mehta PK, Aitcin PC. Microstructural basis for selection of materials and mix

proportions for high strength concrete. Second International Symposium on

High Strength Concrete, ACI SP-121, W.T. Hester, ed., American Concrete

Institute, Farmington Hills, Michigan, USA, 1990, pp265-282.

125. Mehta PK, Monteiro PJM. Concrete: Microstructure, Properties and Materials,

3rd edn. McGraw-Hill, New York, 2006.

126. Mindess S, Young JF, Darwin D. Concrete. 2nd Edition, Prentice Hall, Upper

Saddle River, N.J., 2003, pp644.

127. Mittal A, Kaisare MB, Shetti RG. Use of SCC in a pump house at TAPP 3 & 4,

Tarapur. Indian Concrete Journal, Vol. 78, No. 6, 2004, pp30-34.

128. Monteiro PJM, Maso JC, Ollivier JP. The aggregate-mortar interface. Cement

Concrete Res, Vol. 15, 1985, pp953–8.

129. Montgomery DG. Fly ash in concrete – A microstructure study, Cem Concr Res,

Vol. 11, 1981, pp591–603.

130. Nath P, Sarker P. Effect of Fly Ash on the Durability Properties of High

Strength Concrete. Proceedia Engineering, Vol. 14, 2011, pp1149-1156.

227

131. Nawa T, Izumi T, Edamatsu Y. State-of-the-art report on materials and design of

self-compacting concrete. In: International Workshop on Self-Compacting

Concrete. 1998, pp160-190.

132. Nehdi ML, Pardhan M, Koshowski S. Durability of self-consolidating concrete

incorporating high-volume replacement composite cements. Cement and


133. Nemati KM. Fracture Analysis of Concrete Using Scanning Electron

Microscopy. Scanning, Vol. 19, 1997, pp426-430.

134. Nepomuceno M, Oliveira L. Parameters for self-compacting concrete mortar

phase. High Concrete Structures and Materials, SP253-21, 2008, pp323-40.

135. Neville AM. Hardened Concrete: Physical and Mechanical Aspects,

ACI Monograph 6. 1971, pp48-53.

136. Neville AM. Tecnología del concreto. Tomo I, IMCYC, Editorial Limusa, S.A.

DE C.V., Mexico D.F. 1988.

137. Neville AM. Properties of concrete, 3rd Edition, Longman Scientific &

Technical, UK, 1993.

138. Neville AM. Properties of Concrete (Fourth and Final Edition). John Wiley &

Sons, Inc, New York. 1996.

139. Nocher M. Flowing Smoothly and Quietly. Advanced Concrete and Masonry

Center, Concrete Quarterly, spring 2001, pp198.

140. Noguchi T, Tomosawa F, Nemati KM., Chiaia BM., Fantilli AP. A Practical

Equation for Elastic Modulus of Concrete. ACI Structural Journal, Vol. 106,

No. 5, 2009, pp690-696.

141. Okamura H. Self-compacting high-performance concrete. Concrete

International, Vol. 19, No. 7, 1997, pp50-54.

228

142. Okamura H, Maekawa K, Ozawa K. High performance concrete. Giho-do Press,

Tokyo. 1993.

143. Okamura H, Ouchi M. Self-compacting concrete development, present use and

future. In: The 1st International RILEM Symposium on Self-Compacting

Concrete. Skarendahl A, Petersson O, editors, RILEM Publications. S.A.R.L,

France. 1999, pp3-14.

144. Okamura H, Ouchi M. Applications of self-compacting concrete in Japan. In:

The 3rd International RILEM Symposium on Self-Compacting Concrete.

Wallevik OH, Nielsson I, editors, RILEM Publications S.A.R.L., Bagneux,

France. 2003a, pp3-5.

145. Okamura H, Ouchi M. Self-compacting concrete. Journal of Advanced Concrete

Technology, Vol. 1, No. 1, 2003b, pp 5-15.

146. Okamura H, Ozawa K. Self-compactable high-performance concrete in Japan.

In: International Workshop on High-performance Concrete. 1994, pp1-16.

147. Okamura H, Ozawa K. Mix design for self-compacting concrete. Concrete

Library of Japanese Society of Civil Engineers Vol. 25, No. 6, 1995, pp107-120.

148. Ollivier JP, Maso JC, Bourdette B. Interfacial Transition Zone in Concrete.

Advn Cem Bas Mat, Vol. 2, 1995, pp30-38.

149. Ouchi M, Nakamura S, Osterson T, Hallberg SE, Lwin M. Applications of

self-compacting concrete in Japan, Europe and the United States. Proceedings of

the 3rd PCI/FHWA International Symposium on High Performance Concrete,

US Department of Transportation and Federal Highway Transportation

(FHWA), Orlando, Florida, USA. 2003.

150. Owens, P.L. Adapted and redrawn from Fly ash and its usage in concrete.

Concrete, July, 1979.

229

151. Ozawa K. Utilization of new concrete technology in construction project -

Future prospects of self-compacting concrete. In: The 2nd International RILEM

Symposium on Self-Compacting Concrete. Ozawa K, Ouchi M, editors, 2001,

pp57-62.

152. Ozawa K, Maekawa K, Kunishima M, Okamura H. Development of High

Performance Concrete Based on Durability Design of Concrete Structure,

Proceeding of the Second East- Asia and Pacific Conference on Structural

Engineering and Construction (EASEC-2), Vol.1, January 1989, pp. 445-450.

153. Ozyildirim C, Lane DS. Evaluation of Self-Consolidating Concrete. Final

Report, Virginia Transportation Research Council, Charlottesville, Va., June

2003; pp15.

154. Pai BVB. How economic is self compacting concrete? Indian Concr J 2004.

155. Parra C, Valcuende M, Gomez F. Splitting tensile strength and modulus of

elasticity of self-compacting concrete. Construction and Building Materials,

Vol. 25, No. 1, 2011, pppp201-207.

156. Pedersen B, Smelpass S. The relationship between the rheological properties of

SCC and the corresponding matrix phase. Wallevik OH, Nielsson I, editors,

RILEM Publications S.A.R.L., Bagneux, France. 2003, pp106-121.

157. Pera J, Husson S, Guilhot B. Influence of finely ground limestone on cement

hydration. Cement and Concrete Composites, Vol. 21, No. 2, 1999, pp99-105.

158. Perssoiv B. Technical Report: Japan Society for the promotion of Science,

Report 9803:12, Division of Building Materials, Lund Institute of Technology,

Lund, 1998.

230

159. Peterson O. Final Report of Task 1: Preliminary Mix Design, SCC.

Brite Euram Contract No. BRPR-CT96-0366, February 1998. Available from:

www.civeng.ucl.ac.uk/research/concrete/sccBE.asp.

160. Petersson O, Billberg P, Van BK. A model for self-compacting concrete. In: The

International RILEM Conference on Production Methods and Workability of

Concrete. Bartos PJM, Marrs DL, Cleland DJ, editors, E&FN Spon, London,

1996, pp484-492.

161. Pineaud A, Cabrillac R., Remond S, Pimienta P, Rivillon P. Mechanical

properties of self-compacting concrete - influence of composition parameters.

Proc. of the Second North American Conf. on the Des. and Use of Self

Consolidating Concr. and the Fourth Int. RILEM Symp. on Self-Consolidating

Concr., Center for Advanced Cement-Based Materials (ACBM), Chicago. 2005,

pp863-868.

162. Poppe AM, De Schutter G. Creep and shrinkage of self-compacting concrete. In:

Yu Z, Shi C, Khayat KH, Xie Y, editors. 1st International symposium on design,

performance and use of SCC. Cachan Cedex: RILEM Publications SARL, 2005,

pp329–36.

163. Rashid MA, Mansur MA, ASCE M, Paramasivam P. Correlations between

Mechanical Properties of High-Strength Concrete. Journal of Materials in Civil

Engineering, Vol. 14, No. 3, 2002, pp230-238.

164. Reddi SA. Self Compacting Concrete for the Tallest Building in India. Indian

Concrete Journal, Vol. 2, No. 4, 2011, pp 17-26.

165. RILEM TC 174 SCC. Self compacting concrete State-of-the-art report of

RILEM technical committe 174-SCC. Skarendahl A, Petersson O, editors,

RILEM Publications S.A.R.L., France 2000.

231

166. Roziere E, Granger S, Turcry P, Loukili A. Influence of paste volume on

shrinkage cracking and fracture properties of self-compacting concrete. Cement

Concrete Composites, Vol. 29, 2007, pp626–36.

167. Saeki T, Sasaki K.. A model to predict the Ca/Si ratio of C-S-H in concrete

containing mineral admixtures, 33rd Conference on Our World in Concrete &

Structures, Singapore, 2008.

168. Sakata N, Maruyama K, Minami M. Basic Properties and Effects of Welan Gum

on Self-Consolidating Concrete, Production Methods and Workability of

Concrete. P. J. M. Bartos, D. L. Marrs, and D. J. Cleland, eds., E&FN Spon,

London, 1996, pp 237-252.

169. Saleh AA, Rajeh ZA. Effects of drying conditions, admixtures and specimen

size on shrinkage strains. Cem Concr Res, Vol .36, No. 10, 2006, pp1985-91.

170. Schlumpf J. Self-compacting concrete structures in Switzerland. Tunnelling and

Underground Space Technology, Vol. 19, 2004, pp480.

171. Schmidt M, Lipson H. Distilling Free-Form Natural Laws from Experimental

data. Science, Vol. 324, No. 5923, 2009, pp81-85.

172. Schwartzentruber LD, Le Roy R, Cordin J. Rheological behaviour of fresh

cement pastes formulated from a Self Compacting Concrete (SCC). Cement and


173. Scrivener KL, Crumbie AK, Laugesen P. The interfacial transition zone (ITZ)

between cement paste and aggregate in concrete, Interface Science, Vol. 12,

2004, pp411-421.

174. Scrivener KL, Nemati KM. The percolation of pore space in the cement

paste/aggregate interfacial zone of concrete. Cem Concr Res, Vol. 26, 1996,

pp35–40.

232

175. Sear LKA. Properties and Use of Coal Fly Ash: A Valuable Industrial By-

product. Thomas Telford Ltd, London, U.K, 2001.

176. Shah SP, Chandra S. Critical stress, volume change and microcracking of

concrete. ACI Mater J, Vol. 65, No. 9, 1968, pp770–81.

177. Shah SP, Sankar R. Internal cracking and strain softening response of concrete

under uniaxial compression. ACI Mater J, Vol. 84, No. 3, 1987, pp200–12.

178. Shah SP, Slate FO. Internal microcracking, mortar–aggregate bond and the

stress–strain curve of concrete. In The Structure of Concrete and its Behaviour

under Load (Brooks A. E. and Newman K. (eds)). Cement and Concrete

Association, London, 1965, pp82–92.

179. Shekarchi M, Libre NA, Mehdipour I, Sangtarashha A, Shafieefar A. Shrinkage

of highly flowable mortar reinforced with polypropylene fibre. The 3rd

International Conference – ACF/VCA. 2008, pp210-216.

180. Shindoh T, Matsuoka Y. Development of combination type self-compacting

concrete and evaluation test methods”. J of Adv Concr Technol, Vol. 1, No. 1,

2003, pp26-36.

181. Shen L, Struble LJ, Lange DA. Testing static segregation of SCC. In: The 2nd

North American Conference on the Design and Use of Self-consolidating

Concrete and the 4th International RILEM Symposium on Self-compacting

Concrete. Shan SP, editor, A Hanley Wood Publication, U.S.A. 2005,

pp729-735.

182. Siddique R. Effect of fine aggregate replacement with Class F fly ash on the

mechanical properties of concrete. Cement and Concrete Research, Vol. 33,

No. 4, 2003, pp539-547.

233

183. Siddique R. Properties of self-compacting concrete containing class F fly ash.

Materials and Design, Vol. 32, No. 3, 2011, pp1501-1507.

184. Siddique R, Khan MI. Supplementary Cementing Materials. Springer, New

York, 2011.

185. Sonebi M. Medium strength self-compacting concrete containing fly ash:

Modelling using factorial experimental plans. Cement and Concrete Research,

Vol. 34, No. 7, 2004, pp1199-1208.

186. Sonebi M, Bartos PJM. Self compacting concrete: Task 4 - Properties of

hardened concrete. 2000.

187. SSR. Schedule of rates as per A.P. revised standard data for the year 2012-2013.

Part-I. Andhra Pradesh, India.

188. St John DA. Concrete Petrography, A handbook of investigative techniques,

Wiley & Sons, New York, 1998.

189. Stock AF, Hannant DJ, Williams RIT. The effect of aggregate concentration

upon the strength and modulus of elasticity of concrete. Mag. Concr. Res.,

Vol. 31, No. 109, 1979, pp225-234.

190. Stutzman PE. Scanning Electron Microscopy in Concrete Petrography,

Reprinted from Materials Science of Concrete Special Volume: Calcium

Hydroxide in Concrete (Workshop on the Role of Calcium Hydroxide in

Concrete), Proceedings. J. Skalny, J. Gebauer, I. Odler, eds., The American

Ceramic Society, November, 2000.

191. Su N, Hsu KC, Chai HW. A simple mix design method for self compacting

concrete. Cement and Concrete Research, Vol. 31, No. 12, 2001, pp1799-1807.

234

192. Sukumar B, Nagamani K, Srinivasa RR. Evaluation of strength at earlyages of

self-compacting concrete with high volume fly ash. Construction and Building

Materials, Vol. 22, No. 7, 2008, 1394-1401.

193. Takada K, Pelva G, Walraven JC. The first trial of self-compacting concrete in

the Netherlands according to the Japanese design method. In: The 13th FIP

Congress. 1998b, pp113-115.

194. Tasdemir MA, Tasdemir C, Akyuz S, Jefferson AD, Lydon FD. Evaluation of

strains at peak stresses in concrete: a three-phase composite model approach.

Cement Concrete Res, Vol. 20, 1998, pp301– 18.

195. Teorenau I, Nicolescu LD. The properties of power station fly-ash concrete. In:

Proceedings of the international symposium on the use of PFA in concrete,

Leeds, UK, 1982, pp231–41.

196. Testing-SCC. Measurement of properties of fresh self-compacting concrete

Final report. 2005.

197. The Concrete Society, BRE. Technical report No.62 self-compacting concrete: a

review. Day RTU, Holton IX, editors, Camberley, UK, Concrete Society, Surrey

GU17 9AB, UK. 2005.

198. Tomosawa F, Noguchi T, Onoyama, K. Investigation of Fundamental

Mechanical Properties of High-Strength Concrete, Summariesof Technical

Papers of Annual Meeting of Architectural Institute of Japan, 1990, pp497-498.

199. Tragardh J. Microstructural features and related properties of self compacting

concrete, in: A. Skarendahl, Ö. Petersson (Eds.), Proceedings of the 1st

International RILEM Symposium on Self-Compacting Concrete, Stockholm,

1999, pp175–186.

235

200. Uchikawa H, Hanehara S, Sawaki D. Estimation of the thickness of transition

zone in hardened mortar and concrete and investigation of the relationship

between their thickness and strength development. Concrete Res and Tech,

Vol. 4, 1993, pp1–8.

201. Uchikawa H, Sawaki D, Anehara S. Influence of kind and added timing of

organic admixture on the composition, structure and property of fresh cement

paste. Cement and Concrete Research, Vol. 25, No. 2, 1995, pp353-364.

202. Vachhani SR, Chaudhary R, Jha SM. Innovative use of self compacting concrete

in Metro construction. Indian Concrete Journal, Vol.5, No. 3, 2004, pp27-32.

203. Van Mier JGM. Fracture processes of concrete. CRC. 1997, pp52.

204. Wallevik OH. Rheology - A Scientific Approach to Develop Self-Compacting

Concrete. 3rd International RILEM Symposium on self-compacting concrete,

Reykjavik, Iceland. 2003, pp10.

205. Walraven J. Self-compacting concrete: challenge for designer and researcher.

Combining the 2nd North American Conf. on the Des. and Use of Self-

Consolidating Concr. and the 4th Int. RILEM Symp. on Self-Compacting

Concr., Center for Advanced Cement-Based Materials (ACBM), Chicago. 2005,

pp431-446.

206. Wattanalamlerd C, Ouchi M. Flowability of fresh mortar in self compacting

concrete using fly ash. In: SCC'2005 - China 1st International Symposium on

Design, Performance and Use of Self-Consolidating Concrete. 2005.

207. Wesche K. Fly ash in concrete: Properties and Performance, RILEM Report 7,

1991.

208. Wong HS, Buenfeld NR. Patch microstructure in cement-based materials: fact

or artefact? Cem Concr Res, Vol. 36, No. 5, 2006, pp990–997.

236

209. Wong YL, Lam L, Poon CS, Zhou FP. Properties of fly ash-modified cement

mortar-aggregate interfaces. Cement and Concrete Research, Vol. 29, No. 12,

1999, pp1905-1913.

210. Wong HS, Zobel M, Buenfeld NR, Zimmerman RW. Influence of the interfacial

transition zone and microcracking on diffusivity, permeability and sorptivity of

cement-based materials after drying. Mag Concr Res,;Vol. 61, No. 8, 2009,

pp571-589.

211. Xie Z, Xi Y. Use of recycled glass as a raw material in the manufacture of

Portland cement. Materials and structures, Vol. 35, No. 8, 2002, pp510-515.

212. Xiong G, Liu J, Li G, Xie H. A way of improving interfacial transition zone

between concrete substrate and repair materials, Cem Concr Res, Vol. 32, 2002,

pp1877-1881.

213. Yahia A, Tanimura A, Shimabukuro A, Shimoyama Y. Effect of Rheological

Parameters on Self-Compatibility of Concrete Containing Various Mineral

Admixtures”. Proceedings of the First RILEM International Symposium on

Self-Compacting Concrete, Stockholm, Sweden, Sept. 1999, pp523-535.

214. Yamada K, Takahashi T, Hanehara S, Matsuhisa M. Effects of the chemical

structure on the properties of polycarboxylate-type superplasticizer. Cement and


215. Yammamuro H, Izumi T, Mizunuma T. Study of non-adsorptive viscosity

agents applied to self-compacting concrete. ACI Materials, Vol. 173, 1997,

pp427-444.

216. Ye Y, Bonen D, Shan SP. Fresh properties and segregation resistance of self-

compacting concrete. In: The 2nd North American Conference on the Design

and Use of Self-consolidating Concrete and the 4th International RILEM

237

Symposium on Self-compacting Concrete. Shan SP, editor, A Hanley Wood

Publication, U.S.A. 2005, pp621-627.

217. Ye G, Liu X, De Schutter G, Poppe AM, Taerwe L. Influence of limestone

powder used as filler in SCC on hydration and microstructure of cement pastes.

Cement and Concrete Composites, Vol. 29, No. 2, 2007, pp94-102.

218. Zimbelmann R. A method for strengthening the bond between cement stone and

aggregates, Cem Concr Res, Vol. 17, 1987, pp651–660.

219. Zhang Y, Sun W, Shang L. Mechanical properties of high performance concrete

made with high calcium high sulfate fly ash, Cem Concr Res, Vol. 27, 1997,

pp1093–1098.

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