| Author(s) |
Title |
| D. Bulteel
E. Garcia-Diaz
J.M. Siwak |
Alkali-Aggregate Reaction: A Method to Quantify the Reaction Degree |
| S. Chatterji
N. Thaulow |
Some Fundamental Aspects of Alkali-Silica Reaction |
| S. Diamond |
Chemistry and Other Characteristics of ASR Gels |
| K.E. Kurtis
P.J.M. Monteiro
W. Meyer-Ilse |
Examination of the Effect of LiCl on SR Gel Expansion |
| C. Larive
A. Laplaud
O. Coussy |
The Role of Water in Alkali-Silica Reaction |
| A. Perruchot
J. Lombardi |
Experimental Evaluation of Composition and Volume Variability of Ca-Si Gels, First Products of Alkali-Silica Reaction (ASR) |
| W. Prince
G. Castanier
J.L. Giafferi |
Similarity Between Alkali-Aggregate Reaction and the Natural Alteration of Rocks |
| M. Radonjic
G. Allen
V. Ragnarsdottir
P. Livesey |
Novel Techniques in a Study of the Mechanism of Dedolomitisation in Alkali-Carbonate Reaction |
| M. Tang
M. Deng
Z. Xu |
Comparison Between Alkali-Silica Reaction and Alkali-Carbonate Reaction |
| W. Wieker
C. Hübert
D. Heidemann
R. Ebert |
Some Experiences in Chemical Modelling of the Alkali-Silica Reaction |
| Z. Xu
X. Lan
M. Deng
M. Tang |
A New Accelerated Method for Determining the Potential Alkali-Carbonate Reactivity |
| A. Shayan |
Combined Effects of Alkali-Aggregate Reaction (AAR) and Cathodic Protection Currents in Reinforced Concrete |
| G. Barisone
G. Restivo |
Alkali-Silica Reactivity of Some Italian Opal and Flints Tested Using a Modified Mortar Bar Test |
| M. de Grosbois
E. Fontaine |
Performance of the 60°C – Accelerated Concrete Prism Test for the Evaluation of Potential Alkali-Reactivity of Concrete Aggregates |
| L. Franke
K. Eickemeier
D. Bosold |
Determination of the Reactivity and the Amorphous Component for Opal Sandstones by the Rietveld Method |
| S.A. Freitag
D.A. St John
R. Goguel |
ASTM C1260 and the Alkali Reactivity of New Zealand Greywackes |
| W.J. French
R.J. Howarth |
The Petrographic Diagnosis of Potentially Deleterious Aggregates |
| D. Glauz
V. Jain |
California’s Experience with Reactive Aggregates |
| J.S. Guédon-Dubied
G. Cadoret
V. Durieux
F. Martineau
P. Fasseu
V. Van Overbecke |
Study on Tournai Limestone in Antoing Cimescaut Quarry Petrological, Chemical and Alkali Reactivity Approach |
| M.H. Shehata
M.D.A. Thomas |
The Effects of Silica Fume and Fly Ash Hydration Products on the Chemistry of the Pore Solution and Portlandite Consumption |
| R. G. Sibbick
P. J. Nixon |
Investigation Into the Effects of Metakaolin as a Cement Replacement Material in ASR Reactive Concrete |
| D. B. Stokes
C. E. Manissero
D. M. Roy
R. I. Malek
J. C. Roumain |
Portland Cement Manufacture Containing Lithium for ASR Control |
| M.D.A. Thomas
R. Hooper
D. Stokes |
Use of Lithium-Containing Compounds to Control Expansion in Concrete Due to Alkali-Silica Reaction |
| T. Hao
N. Feng |
Evaluating the Effectiveness of Natural Zeolite in Preventing Expansion Due to ASR by Accelerated Test |
| M.A. Bérubé
J. Frenette
A. Pedneault
M. Rivest |
Laboratory Assessment of the Potential Rate of ASR Expansion of Field Concrete |
| G. Escadeillas
A.C. Gibergues
E. Massias |
A Case Study of Alkali-Silica Reaction in High-Density Concrete |
| G. Escadeillas
E. Massias
A.C. Gibergues |
Case Study of Alkali-Silica Reaction Due to Silica-Fume Pellets in a Mortar Repair |
| V. Jensen |
In-Situ Measurement of Relative Humidity and Expansion of Cracks in Structures Damaged by AAR |
| H. Kagimoto
M. Sato
M. Kawamura |
Evaluation of the Degree of Deterioration in AAR Damaged Concretes and Analysis of Their Pore Solutions |
| C. Lee
S.W. Sheu
K.C. Chen
J.L. Ko
C.C. Rau |
Field AAR Inspection for the Four Harbors in Taiwan |
| C. Larive
M. Joly
O. Coussy |
Heterogeneity and Anisotropy in ASR – Affected Concrete Consequences for Structural Assessment |
| C. Larive
F. Toutlemonde
M. Joly
A. Laplaud
F. Derkx
E. Merliot
S. Multon |
Structural Effects of ASR in France on Real and Laboratory Structures |
| Y. Kubo
A. Hattori
S. Kurihara
T. Miyagawa |
Long Term Effect of Silane Treatments on Expansion Due to Alkali-Silica Reaction by Water Control |
| D.B. Stokes
M.D.A. Thomas
S.G. Shashiprakash |
Development of Lithium-Based Material for Decreasing ASR-Induced Expansion in Hardened Concrete |
| D. Whitmore
S. Abbott |
Use of An Applied Electric Field to Drive Lithium Ions into Alkali-Silica Reactive Structures |
| G. Baillemont
J.B. Delaby |
Diagnosis, Treatment and Monitoring of a Bridge Damaged by AAR |
| G.E. Blight
Y. Ballim |
Properties of AAR-Affected Concrete Studied Over 20 Years |
| A. Carse |
The Asset Management of Alkali-Silica Reaction in the Queensland Road Bridge Network, an Owner’s Viewpoint |
| J.A. den Uijl
N. Kaptijn
J.C. Walraven |
Shear Resistance of Flat Slab Bridges Affected by ASR |
| D.L. Gress
R.L. Kozikowski |
Accelerated ASR Testing of Concrete Prisms Incorporating Recycled Concrete Aggregates |
| K. Ono
M. Taguchi |
Long-Term Behavior of AAR Bridge Pier and the Internal Deterioration |
| M.A. Ozol |
Severe Pavement Damage Caused by Alkali-Silica Reaction in Limestone Coarse Aggregate Containing Very Fine Quartz Particles |
| J. Ryell
R. Mlynarczyk
R. Falcioni |
Rehabilitation of a Major 38 Year Old Structure Characterized by Severe Alkali-Aggregate Reactivity |
| A.J.M. Siemes
J.D. Bakker |
Evaluation of the Institution of Structural Engineers’ Procedure on Concrete Structures with Alkali-Silica Reaction in the Netherlands |
| T. Siemes
J. Gulikers |
Monitoring of Reinforced Concrete Structures Affected by Alkali-Silica Reaction |
| M.C. Thomson |
Field Installation in Pennsylvania to Assess SHRP Recommendations for ASR Control: Part 2 Laboratory Testing of Job Material |
| K. Torii
Y. Kumagai
Y. Okuda
K. Ishii
K. Sato |
Strengthening Method for ASR Affected Concrete Piers Using Prestressing Steel Wire |
| A.J.C.T Cavalcanti
A.T. Campos |
Rehabilitation of a Generating Unit Affected by Alkali-Aggregate Reaction |
| A.J.C.T Cavalcanti
J.F.A. Silveira
J.C. Degaspare |
AAR Management at Paulo Afonso IV Power Plant – Brazil |
| D.D. Curtis |
A Review and Analysis of AAR-Effects in Arch Dams |
| D.D. Curtis |
Analysis and Structure Response to Recent Slot Cutting at Mactaquac Generating Station |
| M. Gaudreault |
The St. Lawrence Seaway (Québec, Canada): A Case Study in the Management of Structures Affected by Alkali-Aggregate Reaction |
| V. Gocevski
S. Pietruszczak |
Assessment of the Effects of Slot-Cutting in Concrete Dams Affected by Alkali-Aggregate Reaction |
| D. Hooton
C.R. Donnelly
B. Clarida
C.A. Rogers |
An Assessment of the Effectiveness of Blast-Furnace Slag in Counteracting the Effects of Alkali-Silica Reaction |
| S.C. Kuperman
J.C. dal Fabbro
S. Cifú
H. Kako
F. Tavares
W.V.F. Ferreira
A.C.A. Werneck
V.L.A. Sardinha |
Management of a Water Intake Affected by Alkali-Aggregate Reaction |
| D. MacMillan
G. McPhail |
Assessment and Monitoring of Pointe Du Bois G.S. Powerhouse |
| R.A. Magalhães
A.L.C. Carim
A.M. Costa
C.N. Moura
M. Shaat |
Management of Structures of Peti Dam Affected by AAR |
| S.T.R. (Scott) Roy |
The Identification of Alkali-Aggregate Reaction at the Gardiner Dam, Outlook Saskatchewan |
| A. Shayan
R.E. Wark
A. Moulds |
Diagnosis of AAR in Canning Dam, Characterisation of the Affected Concrete and Rehabilitation of the Structure |
| J.F.A. Silveira
J.C. Degaspare
A.J.C.T.Cavalcanti |
Diagnosis of the Cause of the Progressive Concrete Swelling at the Paulo Afonso I, II, and III Underground Power Stations |
