Environmental Engineering Reference
In-Depth Information
128.
Chi, J.M., Huang, R., and Yang, C.C., Effects of carbonation on mechanical properties
and durability of concrete using accelerated testing method, Journal of Marine Sci-
ence and Technology 10, 14, 2002.
129.
Dewaele, P.J., Reardon, E.J., and Dayal, R., Permeability and porosity changes asso-
ciated with cement grout carbonation, Cement and Concrete Research 21, 441, 1991.
130.
Dias, W.P.S., Reduction of concrete sorptivity with age through carbonation, Cement
and Concrete Research 30, 1255, 2000.
131.
Freyssinet, P. et al., Chemical changes and leachate mass balance of municipal solid
waste bottom ash submitted to weathering, Waste Management 22, 159, 2002.
132.
Houst, Y.F., Microstructural changes of hydrate cement paste due to carbonisation,
in Mechanisms of Chemical Degradation of Cement-based Systems , Scrivener, K.L.
and Young, J.F., Eds., E&FN Spon, London, 1997, p. 90.
133.
Kobayashi, K., Suzuki, K., and Uno, Y., Carbonation of concrete structures and
decomposition of C-S-H, Cement and Concrete Research 24, 55, 1994.
134.
Lange, L.C., Hills, C.D., and Poole, A.B., The effect of accelerated carbonation on
the properties of cement-solidified waste forms, Waste Management 16, 757, 1996.
135.
Lange, L.C., Hills, C.D., and Poole, A.B., Effect of carbonation on properties of
blended and non-blended cement solidified waste forms, Journal of Hazardous Mate-
rials 52, 193, 1997.
136.
Maslehuddin, M., Shirokoff, J., and Siddiqui, M.A.B., Changes in the phase compo-
sition in OPC and blended cement mortars due to carbonation, Advances in Cement
Research 8, 167, 1996.
137.
Nishikawa, T. et al., Decomposition of synthesized ettringite by carbonation, Cement
and Concrete Research 22, 6, 1992.
138.
Papadakis, V.G., Vayenas, C.G., and Fardis, M.N., Experimental investigation and
mathematical modeling of the concrete carbonation problem, Chemical Engineering
Science 46, 1333, 1991.
139.
Roy, S.K., Poh, K.B., and Northwood, D.O., Durability of concrete — accelerated
carbonation and weathering studies, Building and Environment 34, 597, 1999.
140.
Van Gerven, T. et al., Influence of carbonation and carbonation methods on leaching
of metals from mortars, Cement and Concrete Research 34, 149, 2004.
141.
Walton, J.C. et al., Role of carbonation in transient leaching of cementitious waste-
forms, Environmental Science and Technology 31, 1997.
142.
Walton, J.C. et al., Role of carbonation in long-term performance of cementitious
wasteforms, in Mechanisms of Chemical Degradation of Cement-based Systems ,
Scrivener, K.L. and Young, J.F., Eds., E&FN Spon, London, 1997, p. 315.
143.
Baroghel-Bouny, V. et al., Characterization and identification of equilibrium and
transfer moisture properties for ordinary and high-performance cementitious materi-
als, Cement and Concrete Research 29, 1225, 1999.
144.
Akita, H., Fujiwara, T., and Ozaka, Y., Practical procedure for the analysis of moisture
transfer within concrete due to drying, Magazine of Concrete Research 49, 129, 1997.
145.
van Breugel, K. and Koenders, E.A.B., Numerical simulation of hydration-driven
moisture transport in bulk and interface paste in hardened concrete, Cement and
Concrete Research 30, 1911, 2000.
146.
Numao, T., Mihashi, H., and Fukuzawa, K., Moisture migration and drying properties
of hardened cement paste and mortar, Nuclear Engineering and Design 156, 139,
1995.
147.
Ayano, T. and Wittmann, F.H., Drying, moisture distribution, and shrinkage of
cement-based materials, Materials and Structures 35, 2002.
Search WWH ::




Custom Search