Mauro Marangoni scite author profile

The stabilization of inorganic waste of various nature and origin, in glasses, has been a key strategy for environmental protection for the last decades. When properly formulated, glasses may retain many inorganic contaminants permanently, but it must be acknowledged that some criticism remains, mainly concerning costs and energy use. As a consequence, the sustainability of vitrification largely relies on the conversion of waste glasses into new, usable and marketable glass‐based materials, in the form of monolithic and cellular glass‐ceramics. The effective conversion in turn depends on the simultaneous control of both starting materials and manufacturing processes. While silica‐rich waste favours the obtainment of glass, iron‐rich wastes affect the functionalities, influencing the porosity in cellular glass‐based materials as well as catalytic, magnetic, optical and electrical properties. Engineered formulations may lead to important reductions of processing times and temperatures, in the transformation of waste‐derived glasses into glass‐ceramics, or even bring interesting shortcuts. Direct sintering of wastes, combined with recycled glasses, as an example, has been proven as a valid low‐cost alternative for glass‐ceramic manufacturing, for wastes with limited hazardousness. The present paper is aimed at providing an up‐to‐date overview of the correlation between formulations, manufacturing technologies and properties of most recent waste‐derived, glass‐based materials. © 2016 The Authors. Journal of Chemical Technology & Biotechnology published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.

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Sintered and glazed glass-ceramics from natural and waste raw materials

Binhussain

Marangoni

Bernardo

et al. 2014

Ceramics International

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Porous, Sintered Glass‐Ceramics from Inorganic Polymers Based on Fayalite Slag

et al. 2016

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The present paper deals with the synthesis of porous, sintered glass-ceramics obtained at temperatures below 1150°C, originating from inorganic polymers based on fayalite slag. Firing led to the evaporation of water, dehydroxylation, and oxidation of Fe2+ above 345°C. For heating >700°C, the Si-O stretching band shifted from the 1160 and 750 cm-1 to the 1255 and 830 cm-1 region, due to a structural reorganization of the amorphous phase, whereas Fe-O bands appeared at 550 cm-1. The final microstructure consisted predominantly of an amorphous phase, hematite, and franklinite. The open porosity and compressive strength decreased and increased, respectively, as the firing temperature increased. The final values suggest properties comparable to that of structural lightweight concrete, still, the materials synthesized herein, are lighter, and made primarily from secondary resources

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Mauro Marangoni

Recycling of inorganic waste in monolithic and cellular glass‐based materials for structural and functional applications

Sintered and glazed glass-ceramics from natural and waste raw materials

Porous, Sintered Glass‐Ceramics from Inorganic Polymers Based on Fayalite Slag

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