The impact of organic compounds on the processing and reactivity of inorganic materials has been a source of inspiration for materials scientists for decades and continues to trigger novel and innovative applications in a broad range of disciplines. However, molecular design of such compounds to reach targeted properties remains challenging, particularly for reactive and multicomponent systems. This outstanding challenge is met here by combining a model cement, hosting different coupled reactions of dissolution, nucleation and growth, together with comb-copolymers that offer large and well-controlled variations of their molecular architecture. We show that silicate reactivity is affected by a combination of molecular and submolecular scale effects of these polymers. The first can be described by scaling laws from polymer physics, whereas the second involves specific chemical interactions. In particular, the ability of these polymers to hinder dissolution appears to be crucial, something for which strong experimental evidence is provided.
CITATION STYLE
Marchon, D., Juilland, P., Gallucci, E., Frunz, L., & Flatt, R. J. (2017). Molecular and submolecular scale effects of comb-copolymers on tri-calcium silicate reactivity: Toward molecular design. Journal of the American Ceramic Society, 100(3), 817–841. https://doi.org/10.1111/jace.14695
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