Potential of rice husk ash for mitigating the alkali-silica reaction in mortar bars incorporating reactive aggregates
暂无分享,去创建一个
[1] A. Neville. Properties of Concrete , 1968 .
[2] P. Wedding,et al. The Effect of Fly Ash on Concrete Alkali-Aggregate Reaction , 1981 .
[3] J. Gillott,et al. Mechanism of alkali-silica reaction and the significance of calcium hydroxide , 1991 .
[4] G. Walters,et al. Effect of Metakaolin on Alkali-Silica Reaction (ASR) in Concrete Manufactured With Reactive Aggregate , 1991, "SP-126: Durability of Concrete: Second International Conference, Montreal, Canada 1991".
[5] K. Pettersson. Effects of silica fume on alkali-silica expansion in mortar specimens , 1992 .
[6] J. Lumley. The ASR expansion of concrete prisms made from cements partially replaced by ground granulated blastfurnace slag , 1993 .
[7] Michael D.A. Thomas,et al. Field studies of fly ash concrete structures containing reactive aggregates , 1996 .
[8] Surendra P. Shah,et al. SHRINKAGE CRACKING OF HIGH-STRENGTH CONCRETE , 1996 .
[9] C. Hwang,et al. The use of rice husk ash in concrete , 1996 .
[10] G. Sposito,et al. Influence of mineral admixtures on the alkali-aggregate reaction , 1997 .
[11] Michael D. A. Thomas,et al. Microstructural Studies of Alkali-Silica Reaction in Fly Ash Concrete Immersed in Alkaline Solutions , 1998 .
[12] W. Aquino,et al. The influence of metakaolin and silica fume on the chemistry of alkali-silica reaction products , 2001 .
[13] A. Siemes,et al. Unexpectedly low tensile strength in concrete structures , 2002 .
[14] Michael D. A. Thomas,et al. The effect of the silica content of silica fume on its ability to control alkali–silica reaction , 2003 .
[15] A. Moropoulou,et al. Evaluation of pozzolanic activity of natural and artificial pozzolans by thermal analysis , 2004 .
[16] V. Jensen. Alkali–silica reaction damage to Elgeseter Bridge, Trondheim, Norway: a review of construction, research and repair up to 2003 , 2004 .
[17] M. Richardson,et al. A study of the influence of slag alkali level on the alkali-silica reactivity of slag concrete , 2005 .
[18] A. E. F. S. Almeida,et al. Thermogravimetric analyses and mineralogical study of polymer modified mortar with silica fume , 2006 .
[19] Michael D.A. Thomas,et al. Selection of an effective ASR-prevention strategy for use with a highly reactive aggregate for the reconstruction of concrete structures at Mactaquac generating station , 2010 .
[20] M. Salleh,et al. Contribution of Rice Husk Ash to the Properties of Mortar and Concrete: A Review , 2010 .
[21] Michael D. A. Thomas,et al. The effect of supplementary cementing materials on alkali-silica reaction: A review , 2011 .
[22] Tanvir Hossain,et al. Utilization potential of rice husk ash as a construction material in rural areas , 2011 .
[23] D. Baruah,et al. Crop residue biomass for decentralized electrical power generation in rural areas (part 1): Investigation of spatial availability , 2011 .
[24] P. Rivard,et al. Influence of supplementary cementitious materials on engineering properties of high strength concrete , 2011 .
[25] R. Zerbino,et al. Alkali–silica reaction in mortars and concretes incorporating natural rice husk ash , 2012 .
[26] Sharifah Rafidah Wan Alwi,et al. A review on utilisation of biomass from rice industry as a source of renewable energy , 2012 .
[27] Farshad Rajabipour,et al. How does fly ash mitigate alkali–silica reaction (ASR) in accelerated mortar bar test (ASTM C1567)? , 2013 .
[28] P. Tsakiridis,et al. Dry-grinded ultrafine cements hydration. physicochemical and microstructural characterization , 2013 .
[29] P. Rangaraju,et al. Decoupling the effects of chemical composition and fineness of fly ash in mitigating alkali-silica reaction , 2013 .
[30] F. C. Lai,et al. Fabrication of a non-cement binder using slag, palm oil fuel ash and rice husk ash with sodium hydroxide , 2013 .
[31] M. Islam,et al. Time Series analysis for prediction of ASR-induced expansions , 2013 .
[32] Mohammad Asadullah,et al. Barriers of commercial power generation using biomass gasification gas: A review , 2014 .
[33] M. Shehata,et al. The capacity of ternary blends containing slag and high-calcium fly ash to mitigate alkali silica reaction , 2014 .
[34] S. Antiohos,et al. Rice husk ash (RHA) effectiveness in cement and concrete as a function of reactive silica and fineness , 2014 .
[35] R. Zerbino,et al. Evaluation of alkali–silica reaction in concretes with natural rice husk ash using optical microscopy , 2014 .
[36] Halit Yazici,et al. Mitigation of Detrimental Effects of Alkali-Silica Reaction in Cement-Based Composites by Combination of Steel Microfibers and Ground-Granulated Blast-Furnace Slag , 2014 .
[37] H. T. Le,et al. Alkali silica reaction in mortar formulated from self-compacting high performance concrete containing rice husk ash , 2015 .
[38] Shuangzhen Wang. Cofired biomass fly ashes in mortar: Reduction of Alkali Silica Reaction (ASR) expansion, pore solution chemistry and the effects on compressive strength , 2015 .
[39] A. Poursaee,et al. The potential of ground clay brick to mitigate Alkali–Silica Reaction in mortar prepared with highly reactive aggregate , 2015 .
[40] M. Islam. Prediction of ultimate expansion of ASTM C 1260 for various alkali solutions using the proposed decay model , 2015 .
[41] P. Rangaraju,et al. Influence of fineness of ground recycled glass on mitigation of alkali–silica reaction in mortars , 2015 .
[42] A. Poursaee,et al. The influence of waste crumb rubber in reducing the alkali–silica reaction in mortar bars , 2015 .
[43] Anwar Khitab,et al. Exploratory study on the effect of waste rice husk and sugarcane bagasse ashes in burnt clay bricks , 2016 .
[44] S. Mor,et al. Application of agro-waste rice husk ash for the removal of phosphate from the wastewater , 2016 .
[45] R. Pode. Potential applications of rice husk ash waste from rice husk biomass power plant , 2016 .
[46] Safeer Abbas,et al. Manufacturing of sustainable clay bricks: Utilization of waste sugarcane bagasse and rice husk ashes , 2016 .