Conventional Precursors and Activators
Luiz Miranda de Lima (TU Delft - Materials and Environment, Paebbl)
Susan A. Bernal (University of Leeds)
Yuyan Huang (University of Leeds)
Alastair T.M. Marsh (University of Leeds)
Elijah D. Adesanya (University of Oulu)
Tero Luukkonen (University of Oulu)
Juho Yliniemi (University of Oulu)
Guang Ye (TU Delft - Materials and Environment)
John L. Provis (Paul Scherrer Institut)
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Abstract
Among the various examples of sustainable construction materials explored in scientific literature, alkali-activated materials excel as one of the most mature and reliable solutions for large scale applications. It consists on the combination of an alkaline source in liquid or solid state, and a partially-to-fully amorphous solid precursor. The combination of these components leads to the obtainment of a hardened material which resembles Portland-cement based products. The performance and durability of these alternative binders is highly dependent on their components and production methods, and multiple laboratorial- and industrial-scale examples have shown their capability of outperforming conventional building materials. Practical challenges with variations in chemistry and mineralogy of raw materials, and the global utilization of prescriptive standards for structural building materials, hinder a wider utilization of these binders, and the efforts of the scientific and applied industry communities in overcoming these barriers is detailed throughout this report. This chapter provides an overview of alkali-activated binders, summarizing the main characteristics of their components, their reaction mechanisms, their challenges, and the expected advances of the technology with respect to one-part binders.