Table of Contents
-Investigation into the Long-Term In-Situ Performance of
High Fly Ash Content Concrete Used for Structural
Applications, by M.R.H. Dunstan, M.D.A. Thomas,
J.B. Cripwell, and D.J. Harrison
-Influence of Residual Carbon in Fly Ash on Microstructure
and Strength Development of Mortars and Concretes,
by H. Hornain, F. Miersman, and J. Marchand
-Properties of High Strength Concrete Using "Classified Fly Ash",
by K. Ukita, M. Ishii, K. Yamamoto, K. Azuma, and K. Kohno
-The Effect of Curing on the Strength Development of Mortar
Containing High Volumes of Fly Ash, by L. Vandewalle and
F. Mortelmans
-Mineralogical Investigations of High-Lime Fly Ashes, by
M. Tokyay and F.H. Hubbard
-Properties of Mortar Containing Ultra-Fine Fly Ash Particles,
by E. Tazawa, A. Yonekura, K. Kawai, H. Kohata, and H. Teramoto
-Properties of Low-Heat Generating Concrete Containing Large
Volumes of Blast-Furnace Slag and Fly Ash, by K. Kanazawa,
K. Yamada, and S. Sogo
-Strength Characteristics of Flowable Mortars Containing Coal
Ash, by C.I. Lai
-Pore Structure and Chloride Permeability of Concretes Containing
Fly Ash, Blast-Furnace Slag and Silica Fume, by K. Torii and
M. Kawamura
-Deicer Salt Scaling Resistance of Roller-Compacted Concrete
Pavements Containing Fly Ash and Silica Fume, by J. Marchand,
M. Pigeon, J. Boisvert, H.L. Isabelle, and O. Houdusse
-Influence of Mechanical Strength and Curing Methods on Sea
Water Durability of Mortars Containing Fly Ashes and Slag,
by A.M. Paillère, G. Platret, P. Roussel, and J. Gawsewitch
-Resistance of Fly Ash Concrete to Freezing and Thawing,
by K.W. Nasser and P.S.H. Lai
-Combined Effect of Carbonation and Chloride on Corrosion
of Reinforcement in Fly Ash Concrete, by S. Nagataki and H. Ohga
-Influence of Fly Ash on Concrete Carbonation and Rebar
Corrosion, by C. Branca, R. Fratesi, G. Moriconi, and S. Simoncini
-Influence of Fly Ash and Moist Curing Time on Concrete
Permeability, by S.L. Marusin
-Investigations on the Sulfate Resistance of High-Lime Fly Ash
Incorporating PC-fa Mortars, by T.Y. Erdo?an, M. Tokyay, and
K. Ramyar
-Effects of Intergrinding Fly Ash on the Sulfate Resistance of
Fly Ash Concrete, by R.B. Freeman and R.L. Carrasquillo
-Strength and Fracture Energy of Concrete With and Without
Fly Ash Cured in Water at Different Constant Temperatures,
by J.J. Brooks and Z.D. Sikharulidze
-Concrete Incorporating High Volumes of ASTM Class F Fly
Ashes: Mechanical Properties and Resistance to Deicing
Salt Scaling and to Chloride-Ion Penetration, by A. Bilodeau
and V.M. Malhotra
-Study on Properties of Concrete with Ultra-Fine Particles
Produced from Fly Ash, by Y. Matsufuji, H. Kohata, K. Tagaya,
H. Teramoto, Y. Okawa, and S. Okazawa
-Performance of a High-Calcium Fly Ash in Roller-Compacted
Concrete, by J. Papayianni
-Utilization of Sorbent Slurry-Injection Modified Fly Ash, by R.C.
Joshi, J.O. Thomas, M. Mozes, and R. Mangal
-Concrete Incorporating a High Volume of ASTM Class C
Fly Ash with High Sulfate Content, by F. Gomà
-Granulation of Fly Ash Lightweight Aggegate and Accelerated
Curing Technology, by C.L. Hwang, R.Y. Lin, K.M. Hsu, and
J.F. Chan
-The Properties of Cements Containing Fly Ash Together with
Other Admixtures, by Z. Giergiczny
-Upgrading of PFA for Utilization in Concrete, by H.A.W.
Cornelissen and C.H. Gast
-A Comparative Study of Natural Pozzolans Used in Blended
Cement Production, by M.S. Akman, F. Mazlum, and F. Esenli
-Evaluation of Pozzolanic Activity of Rice Husk Ash, by
S. Sugita, M. Shoya, and H. Tokuda
-Strength of Mortar Made with Cement Containing Rice Husk
Ash and Cured in Sodium Sulphate Solution, by F. Mazlum
and M. Uyan
-The Mitigating Effect of Pozzolans on Alkali Silica Reactions,
by M. Geiker and N. Thaulow
-Evaluation of Testing Methods Used for Assessing the
Effectiveness of Mineral Admixtures in Suppressing Expansion
Due to Alkali-Aggregate Reaction, by M.A. Bérubé and
J. Duchesne
-Effect of Fly Ash on Alkali-Aggregate Reaction in Marine
Environment, by H. Ohga and S. Nagataki
-The Role of High Volume Fly Ash in Controlling Alkali-Aggregate
Reactivity, by S. Ramachandran, V. Ramakrishnan, and
D. Johnston
-Comparative Study of Natural Zeolites and Other Inorganic
Admixtures in Terms of Characterization and Properties of
Mortars, by Y. Kasai, K. Tobinai, E. Asakura, and N. Feng
-Microstructure of Cement-Based Grouts Containing Fly Ash and
Brine, by A.A. Al-Manaseer, M.D. Haug, and L.C. Wong
-Effect of Mineral Admixtures on the Cement Paste-Aggregate
Interface, by J.A. Larbi and J.M. Bijen
-Effects of the Use of Sulfitic Fly Ash in Mortars and Concretes,
by A. Carles-Gibergues and B. Husson
-Fly Ash Concrete Containing Petroleum Contaminated Soils,
by A.S. Ezeldin, D.A. Vaccari, and R.T. Mueller
-Concrete as an Engineered Alternative to Shallow Land Disposal
of Low Level Nuclear Waste: Overview, by J. Philip and J.R.
Clifton
-Pozzolanic Behavior of Thermally Activated Kaolin, by
J. Ambroise, S. Martin-Calle, and J. Péra
-Pozzolanic Activity of Calcined Red Mud, by J. Péra and
A.S. Momtazi
-The Action of Some Aggressive Solutions on Portland and
Calcined Laterite Blended Cement Concretes, by T. Marwan,
J. Péra, and J. Ambroise
-Minimization of Leaching of Shotcrete by Admixtures, by
R. Breitenbücher, R. Springenschmid, and H.W. Dorner
-The Reaction Mechanism of Blended Cements: A 29Si NMR
Study, by H.S. Pietersen, A.P.M. Kentgens, G.H. Nachtegaal,
W.S. Veeman, and J.M.J.M. Bijen
-Influence of Initial Curing on Pore Structure and Porosity of
Blended Cement Concretes, by P.S. Mangat and J.M. El-Khatib
-Silica Fume in Concrete -- An Overview, by K.H. Khayat and
P.C. Aïtcin
-High Strength Concrete Binders Part A: Reactivity and
Composition of Cement Pastes With and Without Condensed
Silica Fume, H. justnes, E.J. Sellevold, and G. Lundevall
-High Strength Concrete Binders Part B: Nonevaporable Water,
Self-Desiccation and Porosity of Cement Pastes With and
Without Condensed Silica Fume, by E.J. Sellevold and H. Justnes
-Some Moisture Properties of Silica Fume Mortar, by E. Atlassi
-Properties and Microstructure of High-Performance Concretes
Containing Silica Fume, Slag, and Fly Ash, by M. Baalbaki, S.L.
Sarker, P.C. Aïtcin, and H. Isabelle
-Influence of Different Types of Silica Fume Having Varying Silica
Content on the Microstructure and Properties of Concrete, by V.G.
Batrakov, S.S. Kaprielov, and A.V. Sheinfeld
-The Influence of Mix Composition on Mechanical Properties of
High- Performance Silica-Fume Concrete, by F. de Larrard and
R. Le Roy
-Prediction of Strength Development for Silica Fume Concrete,
by M. Sandvik and O.E. Gjorv
-Effect of Mixing Method on Mechanical Properties and Pore
Structure of Ultra High-Strength Concrete, by M. Kakizaki,
H. Edahiro, T. Tochigi, and T. Niki
-Long-Term Strength Development of Silica Fume Concrete,
by G.G. Carette and V.M. Malhotra
-Heat Curing of Concrete With and Without Condensed Silica
Fume -- Effect of Early Temperature History on Compressive
Strength, by P.H. Laamanen, K. Johansen, B.P. Kyltveit, and
E.J. Sellevold
-High Strength Concrete Containing Silica Fume -- Impact of
Aggregate Type on Compressive Strength and E-Modulus,
by J. Lindgård and S. Smeplass
-The Effect of Variable Curing Conditions on the Properties of
Mortars with Silica Fume, by J. Ma?olepszy and J. Deja
-Compressive Strength of Silica Fume Concrete at Higher
Temperatures, by T. Kanda, F. Sakuramoto, and K. Suzuki
-Effect of Chloride-Sulfate Ions on Reinforcement Corrosion
and Sulfate Deterioration in Blended Cements, by
O.S.B. Al-Amoudi, Rasheeduzzafar, S.N. Abduljauwad, and
M. Maslehuddin
-Plastic, Mechanical, Corrosion, and Chemical Resistance
Properties of Silica Fume (Microsilica) Concretes, by N.S. Berke,
M.P. Dallaire, and M.C. Hicks
-Effect of Silica Fume Addition on the Durability of Alkali-Resistant
Glass Fibre in Cement Matrices, by V.T. Y?lmaz and F.P. Glasser
-Durability of High Early Strength Silica Fume Concretes
Subjected to Accelerated and Normal Curing, by C.D. Johnston
-Corrosion Resistance of Normal and Silica Fume-Modified
Mortars Made from Different Types of Cement, by J. Madej
-Fracture and Adhesion Properties of a Carbon Fiber-Cementitious
Composite with Silica Fume Variability in the Matrix, by
A. Di Tommaso, G. Mantegazza, and A.M. Penna
-Fatigue of Reinforced Silica Fume Concrete Beam under the
Environment of Water or Chloride Solution, by N. Takagi,
M. Ikeda, and T. Kojima
-Wet-Mix Silica Fume Shotcrete: Effect of Silica Fume Form,
by D.R. Morgan and J. Wolsiefer, Sr.
-Silica Fume-Polymer Mortars for Rehabilitation of Bridge Decks,
by T.A. Bürge
-Concrete Bridge-Deck Overlays Containing Silica Fume,
by C. Ozyildirim
-The Performance of Portland and Blast Furnace Slag Cement
Concretes in Marine Environments, by G.J. Osborne
-Influence of Slag Type and Replacement Level on Strength,
Elasticity, Shrinkage, and Creep of Concrete, by J.J. Brooks,
P.J. Wainwright, and M. Boukendakji
-Effect of Slag Fineness on the Development of Concrete
Strength and Microstructure, by N. Nakamura, M. Sakai,
and R.N. Swamy
-Properties of Granulated Blast-Furnace Slag Cement Concrete,
by K. Sakai, H. Watanabe, M. Suzuki, and K. Hamazaki
-Properties of Super Low Heat Cement Incorporating Large
Amounts of Ground Granulated Blast Furnace Slag of High
Fineness, by T. Tomisawa, T. Chikada, and Y. Nagao
-Study on the Effects of Blast-Furnace Slag on Properties of
No-Slump Concrete Mixtures, by K. Togawa and J. Nakamoto
-Properties of Concrete Using Newly Developed Low-Heat
Cements and Experiments with Mass Concrete Model, by
S. Nagataki, T. Sone, and A. Matsui
-Utilization of Blast-Furnace Slag and Silica Fume for Controlling
Temperature Rise in High-Strength Concrete, by M. Yurugi,
T. Mizobuchi, and T. Terauchi
-High-Strength Concrete for Wall Foundation Using Ternary
Blended Cement with Intermixture of Blast-Furnace Slag and
Fly Ash, by S. Kashima, N. Furuya, and R. Yamaoka
-Chloride-Ion Attack on Low Water-Cement Ratio Pastes
Containing Silica Fume, by R. Gagné, M. Pigeon, E. Revertégat,
and P.C. Aïtcin
-Degradation of Normal Portland and Slag Cement Concrete under
Load Due to Reinforcement Corrosion, by K.E. Philipose,
J.J. Beaudoin, and R.F. Feldman
-Fatigue of Concrete Composed of Blast Furnace Slag or Silica
Fume under Submerged Conditions, by S. Ozaki and N. Sugata
-Sulfate Resistance of Mortars Containing Ground Granulated
Blast-Furnace Slag with Variable Alumina Content, by
J.P.H. Frearson and D.D. Higgins
-Measurement of Corrosion of Steel Reinforcement under High
Chloride Conditions, by D. Baweja, H. Roper, S Guirguis, and
V. Sirivivatnanon
-Resistance to Freezing and Thawing and Chloride Diffusion of
Anti-Washout Underwater Concrete Containing Blast-Furnace
Slag, by K. Fukudome, K. Miyano, H. Taniguchi, and T. Kita
-Use of Blast-Furnace Slag Cements in the Boreholes in Salt Beds,
by W. Brylicki, J. Ma?olepszy, and S. Stryczek
-Application of High Slag and Fly Ash, Low-Heat Cement to
Antiwashout Underwater Concrete, by S. Kashima, M. Sakamoto,
S. Okada, T. Iho, and Y. Nakagawa
-Studies on Marine Epilithic Organisms to No-Fines Concrete
Using Slag Cement and Portland Cement with Silica Fume,
by M. Tamai and Y. Nishiwaki
-Activation of Slag in Gypsumless Portland Cements, by
J. Hrazdira
-Modulus of Elasticity and Drying Shrinkage of High-Strength
Concrete Containing Silica Fume, by C. Alfes