G. Ye, E. Burstroem, and A. M. Faellman, Utilisation and stabilisation of steelmaking slags, p.57, 1995.

, Inter-Organization Programme for the Sound Management of Chemicals. Inorganic chromium(VI) compounds. Concise international chemical assessment document, n. 78. World Health Organization, International Programme on Chemical Safety, 2013.

, World Health Organization, International Programme on Chemical Safety. Barium: health and safety guide, n. 46. World Health Organization, 1991.

, Vanadium and some vanadium salts: health and safety guide, n. 42 . World Health Organization, Geneve (CH), 1990.

B. B. Lind, A. Fällman, and L. B. Larsson, Environmental impact of ferrochrome slag in road construction, Waste Manage, vol.21, issue.3, pp.255-264, 2001.

P. Chaurand, J. Rose, V. Briois, L. Olivi, J. Hazemann et al., Environmental impacts of steel slag reused in road construction: a crystallographic and molecular (XANES) approach, J. Hazard. Mater, vol.139, issue.3, pp.537-542, 2007.
URL : https://hal.archives-ouvertes.fr/ineris-00963049

A. Van-zomeren, S. R. Van-der-laan, H. B. Kobesen, W. J. Huijgen, and R. N. Comans, Changes in mineralogical and leaching properties of converter steel slag resulting from accelerated carbonation at low CO 2 pressure, Waste Manage, vol.31, pp.2236-2244, 2011.

C. J. Engelsen, H. A. Van-der-sloot, G. Wibetoe, H. Justnes, W. Lund et al., Leaching characterisation and geochemical modelling of minor and trace elements released from recycled concrete aggregates, Cem. Concr. Res, vol.40, issue.12, pp.1639-1649, 2010.

C. J. Engelsen, G. Wibetoe, H. A. Van-der-sloot, W. Lund, and G. Petkovic, Field site leaching from recycled concrete aggregates applied as sub-base material in road construction, Sci. Total Environ, pp.86-97, 2012.

D. M. Italian-ministerial-decree, 201: definition of the criteria for waste acceptance at landfills, 2005.

D. M. Italian-ministerial-decree, 186: identification of nonhazardous waste subject to simplified recovery procedures, 2006.

A. Forschungsgesellschaft-für-straßen-und-verkehrswesen and . Gesteinskörnungen, Ungebundene Bauweisen, Technische Lieferbedingungen für Baustoffgemische und Boden zur Herstellung von Schichten ohne Bindemittel im Straßenbau (TL G SoB-StB 04), 2004.

, Acceptabilité environnementale de matériaux alternatifs en technique routière-Les laitiers sidérurgiques, Service d'Etudes sur les Transports, les Routes et leurs Aménagements (SETRA)

, Disposiciones generales departamento de ordenación del territorio y medio ambiente n 1186, RD, vol.34, 2003.

, Disposiciones generales departamento de ordenación del territorio y medio ambiente n 1524, vol.49, 2009.

, Assessing legal compliance with and implementation of the waste acceptance criteria and procedures by the eu-15, European Commission, 2009.

H. Saveyn, P. Eder, E. Garbarino, L. Muchova, O. Hjelmar et al., Study on Methodological Aspects regarding Limit Values for Pollutants in Aggregates in the Context of the Possible Development of End-Of-Waste Criteria under the EU Waste Framework Directive, Publications Office of the European Union, 2014.

A. M. Faellman and J. Hartlén, Utilisation of electric arc furnace slag in road construction, Environmental Geotechnics, pp.703-708, 1996.

V. Arredondo-torres, A. Romero-serrano, B. Zeifert, J. Cruz-rivera, P. Flores-sánchez et al., Stabilization of MgCr 2 O 4 spinel in slags of the SiO 2 -CaO-MgO-Cr 2 O 3 system, Rev. Metal, vol.42, issue.6, pp.417-424, 2006.

K. Shinoda, H. Hatakeda, N. Maruoka, H. Shibata, S. Kitamura et al., Chemical state of chromium in CaO-SiO 2 base oxides annealed under different conditions, ISIJ Int, pp.1404-1408, 2008.

M. Kuhn, D. Mudersbach, J. M. Baena-liberato, V. De-angelis, D. Capodilupo et al., Chrome Immobilization in EAF Slag from High Alloy Steelmaking-Development of a Slag Treatment Process, 2006.

D. Mudersbach, M. Kuhn, J. Geiseler, and K. Koch, Chrome immobilisation in EAFslags from high-alloy steelmaking: tests at FEhS-institute and development of an operational slag treatment process, Proceedings of the 1st Interntational Slag Valorisation Symposium, pp.101-110, 2009.

E. M. Levin, C. E. Robbins, and H. F. Mcmurdie, Phase Diagrams for Ceramist, vol.1, 1964.

M. Tossavainen, F. Engstrom, Q. Yang, N. Menad, M. Lidstrom-larsson et al., Characteristics of steel slag under different cooling conditions, Waste Manage, vol.27, pp.1335-1344, 2007.

H. Shen, E. Forssberg, and U. Nordström, Physicochemical and mineralogical properties of stainless steel slags oriented to metal recovery, Resour. Conserv. Recy, vol.40, issue.3, pp.72-79, 2004.

C. Shi, Steel slag À its production, processing, characteristics, and cementitious properties, J. Mater. Civ. Eng, vol.16, issue.3, pp.899-1561, 2004.

M. P. Luxán, R. Sotolongo, F. Dorrego, and E. Herrero, Characteristics of the slags produced in the fusion of scrap steel by electric arc furnace, Cem. Concr. Res, vol.30, issue.4, pp.253-260, 2000.

P. E. Tsakiridis, G. D. Papadimitriou, S. Tsivilis, and C. Koroneos, Utilization of steel slag for Portland cement clinker production, J. Hazard. Mater, vol.152, issue.2, pp.805-811, 2008.

L. M. Juckes, The volume stability of modern steelmaking slags, Miner. Process. Extr. Metall, vol.112, pp.177-197, 2003.

A. S. Reddy, R. K. Pradhan, and S. Chandra, Utilization of basic oxygen furnace (BOF) slag in the production of a hydraulic cement binder, Int. J. Miner. Process, vol.79, issue.2, pp.98-105, 2006.

M. Nicolae, I. Vilciu, and F. Zaman, X-ray diffraction analysis of steel slag and blast furnace slag viewing their use for road construction, UPB Sci. Bull. Ser. B, vol.69, issue.2, pp.99-108, 2007.

G. R. Qian, D. D. Sun, J. H. Tay, and Z. Y. Lai, Hydrothermal reaction and autoclave stability of Mg bearing RO phase in steel slag, vol.101, pp.159-164, 2002.

J. M. Manso, M. Losañez, J. A. Polanco, and J. J. Gonzalez, Ladle furnace slag in construction, J. Mater. Civ. Eng, vol.17, issue.5, p.5513, 2005.

J. Geiseler, Use of steelworks slag in Europe, Waste Manage, vol.16, pp.59-63, 1996.

F. Wachsmuth, J. Geiseler, W. Fix, K. Koch, and K. Schwerdtfeger, Contribution to the structure of BOF-slags and its influence on their volume stability, vol.20, pp.279-284, 1981.

G. Qian, D. D. Sun, J. H. Tay, Z. Lai, and G. Xu, Autoclave properties of kirschsteinitebased steel slag, Cem. Concr. Res, vol.32, issue.9, pp.1377-1382, 2002.

, Chromium (VI) Handbook, Indipendet Evironmental Technical Evaluation Group (IETEG), 2004.

S. Barella, A. Gruttadauria, F. Magni, C. Mapelli, and D. Mombelli, Survey about safe and reliable use of EAF slag, ISIJ Int, vol.52, issue.12, pp.2295-2302, 2012.

D. Mombelli, C. Mapelli, A. Gruttadauria, C. Baldizzone, F. Magni et al., Analysis of electric arc furnace slag, Steel Res. Int, pp.1012-1019, 2012.

D. Mombelli, C. Mapelli, A. Gruttadauria, C. Baldizzone, F. Magni et al., Micro-structural and chemical characterization of electric arc furnace slag, Yejin Fenxi/Metall. Anal, vol.32, issue.3, pp.7-13, 2012.

J. R. Young, M. J. How, A. P. Walker, and W. M. Worth, Classification as corrosive or irritant to skin of preparations containing acidic or alkaline substances, without testing on animals, Toxicol. Vitro, vol.2, issue.1, pp.19-26, 1988.

D. Yoon, B. I. Lee, P. Badheka, and X. Wang, Barium ion leaching from barium titanate powder in water, J. Mater. Sci, vol.14, pp.165-169, 2003.

E. Bordes-richard and P. Courtine, Metal Oxides: Chemistry and Application Chapter, 2006.

V. Dimitrov and T. Komatsu, An interpretation of optical properties of oxides and oxide glasses in terms of the electronic ion polarizability and average single bond strength, J. Univ. Chem. Technol. Metall, pp.219-250, 2010.

P. Chaurand, J. Rose, V. Briois, L. Olivi, J. L. Hazemann et al., Environmental impacts of steel slag reused in road construction: A crystallographic and molecular (XANES) approach, J. Hazard. Mater, vol.139, issue.3, pp.537-542, 2007.
URL : https://hal.archives-ouvertes.fr/ineris-00963049

A. Van-zomeren, S. R. Van-der-laan, H. B. Kobesen, W. J. Huijgen, and R. N. Comans, Changes in mineralogical and leaching properties of converter steel slag resulting from accelerated carbonation at low CO 2 pressure, Waste Manage, vol.31, pp.2236-2244, 2011.

H. F. Taylor, Cement Chemistry, pp.38-39, 1990.

J. Pera and A. Amrouz, Development of highly reactive metakaoline from paper sludge, advances in cement based, Materials, vol.7, pp.49-56, 1998.

A. Arper, Phase Diagram 6-II: Materials Science and Technology, vol.2, p.158, 2012.

A. R. West, Solid State Chemistry and Its Applications, 1987.

D. Mombelli, C. Mapelli, S. Barella, A. Gruttadauria, G. L. Saout et al., The efficiency of quartz addition on electric arc furnace (EAF) carbon steel slag stability, J. Hazard. Mater, vol.279, pp.586-596, 2014.

M. Gelfi, G. Cornacchia, and R. Roberti, Investigations on leaching behavior of EAF steel slags, 6th European Slag Conference EUROSLAG 2010, pp.157-169, 2015.

F. Engström, M. L. Larsson, C. Samuelsson, R. Sandström, B. Robinson et al., Leaching behavior of aged steel slags, Steel Res. Int, vol.85, issue.4, pp.607-615, 2014.

R. Baciocchi, G. Costa, A. Polettini, and R. Pomi, Effects of thin-film accelerated carbonation on steel slag leaching, J. Hazard. Mater, vol.286, pp.369-378, 2015.

E. Belhadj, C. Diliberto, and A. Lecomte, Characterization and activation of basic oxygen furnace slag, Cem. Concr. Comput, vol.34, issue.1, pp.34-40, 2012.
URL : https://hal.archives-ouvertes.fr/hal-02445839

C. E. Tilley, The occurrence of an orthorhombic high-temperature form of Ca 2 SiO 4 (Bredigite) in the scawt hill contact-zone and as a constituent of slags, Mineral. Mag, vol.28, pp.255-271, 1948.

, Proceedings of Seventh International FZK/TNO Conference on Contaminated Soil, vol.2, 2000.

G. C. Lai, T. Nojiri, and K. I. Nakano, Studies of the stability of b-Ca 2 SiO 4 doped by minor ions, Cem. Concr. Res, vol.22, issue.5, pp.743-754, 1992.

F. Xiuji and L. Shizong, Investigation of the effect of minor ions on the stability of b-C 2 S and the mechanism of stabilization, Cem. Concr. Res, vol.16, issue.4, pp.90097-90106, 1986.

N. Sano, Reduction of Chromium Oxide in Stainless Steel Slags, Proceedings: 10th International Ferroalloys Congress, 2004.

K. Moritai, T. Shibuya, and N. Sano, Solubility of the chromite in MgO-Al 2 O 3 -SiO 2 -CaO melts at 1600 C in air, Tetsu Hagane, pp.632-639, 1988.

K. Morita, A. Inoue, N. Takayama, and N. Sano, Solubility of MgOÁCr2O3 in MgO-Al 2 O 3 -SiO 2 -CaO slag at 1600 C under reducing conditions, Tetsu Hagane, pp.999-1005, 1988.

G. J. Albertsson, Abatement of Chromium Emissions from Steelmaking Slags-Cr Stabilization by Phase Separation, 2015.

J. Ylipekkala, Quality Management of Chromium Containing Steel Slags from Melt Phase to Cooling, 2015.

, Selected solubility products and formation constants, at 25 C, 1997.

. Verein-deutscher-eisenhu?tenleute, Slag Atlas, 1981.

H. Chuang, W. Hwang, and S. Liu, Effects of graphite, SiO 2 , and Fe 2 O 3 on the crushing strength of direct reduced iron from the Carbothermic reduction of residual materials, Mater. Trans, vol.51, issue.3, pp.488-495, 2010.

H. Chuang, W. Hwang, and S. Liu, Effects of basicity and FeO content on the softening and melting temperatures of the CaO-SiO 2 -MgO-Al 2 O 3 slag system, Mater. Trans, vol.50, issue.6, pp.1448-1456, 2009.

A. Kondratiev and E. Jak, Predicting coal ash slag flow characteristics (viscosity model in the Al 2 O 3 -CaO-"FeO"-SiO 2 system), Fuel, pp.1989-2000, 2001.

I. Jung, Overview of the applications of thermodynamic databases to steelmaking processes, Calphad, vol.34, issue.3, pp.332-362, 2010.