, International Solid Waste Association.: Management of Bottom Ash from WTE Plants-An Overview of Management Options and Treatment Methods, International Solid Waste Association, 2006.

A. , Etat des lieux de la gestion des mâchefers en France. AMORCE, Villeurbanne Cedex, 2012.

. Ministère-de-l'environnement, Chiffres clés des énergies renouvelables -Édition, 2016.

, International Solid Waste Association.: Waste-to-Energy Stateof-the-Art, 2012.

D. H. Vu, K. Wang, J. Chen, B. X. Nam, and B. H. Bac, Glass-ceramic from mixtures of bottom ash and fly ash, Waste Manag, vol.32, pp.2306-2314, 2012.

S. Bethanis, C. R. Cheeseman, and C. J. Sollars, Properties and microstructure of sintered incinerator bottom ash, Ceram. Int, vol.28, issue.02, pp.68-76, 2002.

L. Barbieri, A. Karamanov, A. Corradi, I. Lancellotti, M. Pelino et al., Structure, chemical durability and crystallization behavior of incinerator-based glassy systems, J. Non. Cryst. Solids, vol.354, pp.521-528, 2008.

L. M. Schabbach, F. Andreola, E. Karamanova, I. Lancellotti, A. Karamanov et al., Integrated approach to establish the sinter-crystallization ability of glasses from secondary raw material, J. Non. Cryst. Solids, vol.357, pp.10-17, 2011.

M. Aloisi, A. Karamanov, G. Taglieri, F. Ferrante, and M. Pelino, Sintered glass ceramic composites from vitrified municipal solid waste bottom ashes, J. Hazard. Mater, vol.137, pp.138-143, 2006.

P. Appendino, M. Ferraris, I. Matekovits, and M. Salvo, Production of glass-ceramic bodies from the bottom ashes of municipal solid waste incinerators, J. Eur. Ceram. Soc, vol.24, issue.03, pp.264-268, 2004.

A. Bourtsalas, L. J. Vandeperre, S. M. Grimes, N. Themelis, and C. R. Cheeseman, Production of pyroxene ceramics from the fine fraction of incinerator bottom ash, Waste Manag, vol.45, pp.217-225, 2014.

L. Barbieri, A. Corradi, and I. Lancellotti, Bulk and sintered glassceramics by recycling municipal incinerator bottom ash, J. Eur. Ceram. Soc, vol.20, issue.00, pp.32-39, 2000.

. Sétra, Acceptabilité environnementale de matériaux alternatifs en technique routière -Les mâchefers d'incinération de déchets non dangereux (MIDND), Sétra, 2012.

E. Rambaldi, L. Esposito, F. Andreola, L. Barbieri, I. Lancellotti et al., The recycling of MSWI bottom ash in silicate based ceramic, Ceram. Int, vol.36, pp.2469-2476, 2010.

N. Lopez-ferber, Q. Falcoz, D. P. Minh, J. F. Hoffmann, A. Meffre et al., Flexibility and robustness of a hightemperature air / ceramic thermocline heat storage pilot, J. Energy Storage, vol.21, pp.393-404, 2019.
URL : https://hal.archives-ouvertes.fr/hal-01969631

G. Zanganeh, High-temperature thermal energy storage for concentrated solar power with air as heat transfer fluid, 2014.

X. Py, N. Calvet, R. Olives, A. Meffre, P. Echegut et al., Recycled material for sensible heat based thermal energy storage to be used in concentrated solar thermal power plants, J. Sol. Energy Eng, vol.133, p.31008, 2011.

G. Dejean, Valorisation de laitiers sidérurgiques comme maté-riaux de stockage thermique pour procédés énergétiques durables, 2014.

A. Kere, N. Sadiki, X. Py, and V. Goetz, Applicability of thermal energy storage recycled ceramics to high temperature and compressed air operating conditions, Energy Convers. Manag, vol.88, pp.113-119, 2014.
URL : https://hal.archives-ouvertes.fr/hal-01178176

. European-commission, Document de référence sur les meilleures techniques disponibles -Fabrication des céramiques, European Commission, 2007.

R. Taurino, E. Karamanova, L. Barbieri, S. Atanasova-vladimirova, F. Andreola et al., New fired bricks based on municipal solid waste incinerator bottom ash, Waste Manag. Res, vol.35, pp.1055-1063, 2017.

S. A. Zavattoni, M. C. Barbato, A. Pedretti, G. Zanganeh, and A. Steinfeld, High temperature rock-bed TES system suitable for industrial-scale CSP plant-CFD analysis under charge/discharge cyclic conditions. Energy Procedia, vol.46, pp.124-133, 2014.

. Iupac, Compendium of Chemical Terminology-Gold Book, 2014.

F. Becquart, F. Bernard, N. E. Abriak, and R. Zentar, Monotonic aspects of the mechanical behaviour of bottom ash from municipal solid waste incineration and its potential use for road construction, Waste Manag, vol.29, pp.1320-1329, 2009.

M. N. Rahaman, Ceramic Processing, 2017.

C. R. Cheeseman, S. Monteiro-da-rocha, C. Sollars, S. Bethanis, and A. R. Boccaccini, Ceramic processing of incinerator bottom ash, Waste Manag, vol.23, pp.39-43, 2003.

L. M. Schabbach, F. Andreola, L. Barbieri, I. Lancellotti, E. Karamanova et al., Post-treated incinerator bottom ash as alternative raw material for ceramic manufacturing, J. Eur. Ceram. Soc, vol.32, pp.2843-2852, 2012.

P. Auerkari, Mechanical and physical properties of engineering alumina ceramics, Tech. Res. Cent. Finl, vol.1792, p.26, 1996.

G. Qian, Y. Song, C. Zhang, Y. Xia, H. Zhang et al., Diopside-based glass-ceramics from MSW fly ash and bottom ash, Waste Manag, vol.26, pp.1462-1467, 2006.
DOI : 10.1016/j.wasman.2005.12.009

L. M. Anovitz and J. G. Blencoe, Dry melting of high albite, Am. Mineral, vol.84, pp.1830-1842, 1999.

H. J. Radix and H. J. Brouwers, Self-Compacting concrete: the role of the particle size distribution, International Symposium for High-Performance. Use Self-Consolidating Concrete, pp.26-28, 2005.

Y. K. Kalpakli, Effects of particle size distribution on the refractory properties and corrosion mechanism of ultra-low cement castables, Arch. Mater. Sci. Eng, vol.34, pp.81-88, 2008.