This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Gyurkó, Z., Szijártó, A., & Nemes, R. (2017). Increasing freeze-thaw resistance of concrete by additions of powdered cellular concrete and clay bricks. Procedia Engineering, 193(C), 11–18.GyurkóZ.SzijártóA.NemesR.2017Increasing freeze-thaw resistance of concrete by additions of powdered cellular concrete and clay bricks193C111810.1016/j.proeng.2017.06.180Search in Google Scholar
He, Z., Tang, S. W., Zhao, G. S., & Chen, E. (2016). Comparison of three and one dimensional attacks of freeze-thaw and carbonation for concrete samples. Construction and Building Materials, 127, 596–606.HeZ.TangS. W.ZhaoG. S.ChenE.2016Comparison of three and one dimensional attacks of freeze-thaw and carbonation for concrete samples12759660610.1016/j.conbuildmat.2016.09.069Search in Google Scholar
Łaźniewska-Piekarczyk, B. (2013). The frost resistance versus air voids parameters of high performance self-compacting concrete modified by non-air-entrained and mixtures. Construction and Building Materials, 48, 1209–1220.Łaźniewska-PiekarczykB.2013The frost resistance versus air voids parameters of high performance self-compacting concrete modified by non-air-entrained and mixtures481209122010.1016/j.conbuildmat.2013.07.080Search in Google Scholar
Nemes, R., & Fenyvesi, O. (2013). Frost resistance of LWAC made with different lightweight aggregates in urban environment. CCC 2013 – Concrete Structures in Urban Areas, Wroclaw, Poland, 478–481.NemesR.FenyvesiO.2013Frost resistance of LWAC made with different lightweight aggregates in urban environmentWroclaw, Poland478481Search in Google Scholar
Abed, M., & Nemes, R. (2017). Possibility of Producing Green, Self-Compacting, High Performance Concrete (GSCHPC). Concrete Structures, 18, 21–29.AbedM.NemesR.2017Possibility of Producing Green, Self-Compacting, High Performance Concrete (GSCHPC)182129Search in Google Scholar
Siddique, R., & Klaus, J. (2009). Influence of metakaolin on the properties of mortar and concrete: a review. Applied Clay Science, 43(3–4), 392–400.SiddiqueR.KlausJ.2009Influence of metakaolin on the properties of mortar and concrete: a review433–439240010.1016/j.clay.2008.11.007Search in Google Scholar
Gruber, K. A., Ramlochan, T., Boddy, A., Hooton, R. D., & Thomas, M. D. A. (2001). Increasing concrete durability with high-reactivity metakaolin. Cement and Concrete Composites, 23(6), 479–84.GruberK. A.RamlochanT.BoddyA.HootonR. D.ThomasM. D. A.2001Increasing concrete durability with high-reactivity metakaolin2364798410.1016/S0958-9465(00)00097-4Search in Google Scholar
Cassagnabère, F., Mouret, M., Escadeillas, G., Broilliard, P., & Bertrand, A. (2010). Metakaolin, a solution for the precast industry to limit the clinker content in concrete: mechanical aspects. Construction and Building Materials, 24(7), 1109–1118.CassagnabèreF.MouretM.EscadeillasG.BroilliardP.BertrandA.2010Metakaolin, a solution for the precast industry to limit the clinker content in concrete: mechanical aspects2471109111810.1016/j.conbuildmat.2009.12.032Search in Google Scholar
Zeníšek, M., Vlach, T., & Laiblová, L. (2017). Dosage of Metakaolin in high performance concrete. Key Engineering Materials, 722, 311–315.ZeníšekM.VlachT.LaiblováL.2017Dosage of Metakaolin in high performance concrete72231131510.4028/www.scientific.net/KEM.722.311Search in Google Scholar
Borosnyói, A. (2016). Long term durability performance and mechanical properties of high performance concretes with combined use of supplementary cementing materials. Construction and Building Materials, 112, 307–324.BorosnyóiA.2016Long term durability performance and mechanical properties of high performance concretes with combined use of supplementary cementing materials11230732410.1016/j.conbuildmat.2016.02.224Search in Google Scholar
Nehme, S. G. (2015). Kiegészítőanyagok hatása a szokványos és az öntömörödô betonokra 2. rész. Laboratóriumi vizsgálatok (Effect of supplementary materials on normal and self-compacting concretes 2. Part 2 – Laboratory tests). Építőanyag – Journal of Silicate Based and Composite Materials, 67(2), 72–78.NehmeS. G.2015Kiegészítőanyagok hatása a szokványos és az öntömörödô betonokra 2. rész. Laboratóriumi vizsgálatok(Effect of supplementary materials on normal and self-compacting concretes 2. Part 2 – Laboratory tests).6727278Search in Google Scholar
Fenyvesi, O., & Jankus, B. (2015). Opportunities in recycling AAC waste as aggregate for lightweight concrete. Építőanyag – Journal of Silicate Based and Composite Materials, 67, 66–70.FenyvesiO.JankusB.2015Opportunities in recycling AAC waste as aggregate for lightweight concrete67667010.14382/epitoanyag-jsbcm.2015.11Search in Google Scholar
European Committee for Standardization (CEN). CEN/TS 12390-9 Testing hardened concrete – Part 9: Freeze-thaw resistance – Scaling, 24.Search in Google Scholar
Szijártó, A. (2016). Performance studies of concretes containing perlite supplementary cementitious material (Bachelor Thesis, Budapest University of Technology and Economics). Hungary, Budapest.SzijártóA.2016(Bachelor Thesis, Budapest University of Technology and Economics). Hungary, BudapestSearch in Google Scholar