Yan, YuScrivener, Karen L.Yu, ChengOuzia, AlexandreLiu, Jiaping2021-03-262021-03-262021-03-262021-03-0110.1016/j.cemconres.2020.106325https://infoscience.epfl.ch/handle/20.500.14299/176444WOS:000608764100006Temperature rise inhibitor (TRI) modifies the exothermic process of cement hydration at early age and mitigates the buildup of cumulative heat, which sheds new light on solving the thermal cracking issue. After the main hydration peak, a broader "second peak" appears and brings the cumulative heat back to normal level within 7 days (for additions less than 0.15%). This study shows that the "second peak" can be attributed, almost exclusively, to C3S hydration while triggered by C(3)A hydration. In a pure C3S system, the heat flow is depressed by TRI during the main hydration peak but never recovers after. In a monophase system composed of C3S, C(3)A and gypsum or a real cement paste, the ongoing precipitation of ettringite helps to pump out TRI polymer from the pore solution and eliminate the restriction on C-S-H nucleation. Afterwards, the precipitation of C-S-H accelerates again to form the "second peak".Construction & Building TechnologyMaterials Science, MultidisciplinaryMaterials Sciencecement hydrationadmixturec-s-hlater ageordinary portland-cementpore solutionheat-flowaliteopcretardersmodeltext::journal::journal article::research article