Please use this identifier to cite or link to this item: http://hdl.handle.net/11452/27181
Title: Immobilization of antimony waste slag by applying geopolymerization and stabilization/solidification technologies
Authors: Uludağ Üniversitesi/Mühendislik Fakültesi/Çevre Mühendisliği Bölümü.
Salihoğlu, Güray
AAG-9399-2021
8551769300
Keywords: Fly-ash
Solidifications-stabilization
Portland-cement
Solid-wastes
Lime
Mechanism
Metal
SB
Engineering
Environmental sciences & ecology
Meteorology & atmospheric sciences
Arsenic
Blast furnaces
Compressive strength
Efficiency
Fly ash
Geopolymers
Gypsum
Hazards
Industrial waste disposal
Inorganic polymers
Leaching
Ores
Portland cement
Silicates
Slags
Sodium hydroxide
Stabilization
European waste catalogues
Geopolymer matrix
Geopolymerization
Immobilization mechanisms
Leaching potential
Sodium hydroxide solutions
Stabilization/solidification
Unconfined compressive strength
Antimony
Issue Date: 2-Nov-2014
Publisher: Taylor & Francis
Citation: Salihoğlu, G. (2014). "Immobilization of antimony waste slag by applying geopolymerization and stabilization/solidification technologies". Journal of the Air and Waste Management Association, 64(11), 1288-1298.
Abstract: During the processing of antimony ore by pyrometallurgical methods, a considerable amount of slag is formed. This antimony waste slag is listed by the European Union as absolutely hazardous waste with a European Waste Catalogue code of 10 08 08. Since the levels of antimony and arsenic in the leachate of the antimony waste slag are generally higher than the landfilling limits, it is necessary to treat the slag before landfilling. In this study, stabilization/solidification and geopolymerization technologies were both applied in order to limit the leaching potential of antimony and arsenic. Different combinations of pastes by using Portland cement, fly ash, clay, gypsum, and blast furnace slag were prepared as stabilization/solidification or geopolymer matrixes. Sodium silicate-sodium hydroxide solution and sodium hydroxide solution at 8 M were used as activators for geopolymer samples. Efficiencies of the combinations were evaluated in terms of leaching and unconfined compressive strength. None of the geopolymer samples prepared with the activators yielded arsenic and antimony leaching below the regulatory limit at the same time, although they yielded high unconfined compressive strength levels. On the other hand, the stabilization/solidification samples prepared by using water showed low leaching results meeting the landfilling criteria. Use of gypsum as an additive was found to be successful in immobilizing the arsenic and antimony.
URI: https://doi.org/10.1080/10962247.2014.943352
https://www.tandfonline.com/doi/full/10.1080/10962247.2014.943352
http://hdl.handle.net/11452/27181
ISSN: 1096-2247
2162-2906
Appears in Collections:Scopus
Web of Science

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