Potassium alum thermal decomposition study under non-reductive and reductive conditions

Potassium alum thermal decomposition study under non-reductive and reductive conditions

Potassium sulfate (K2SO4) is a very important compound, mostly used as nutrient for plant growth. Potassium sulfate production can be accomplished through the Mannheim process. For potassium bearing silicate minerals, such as glauconite, one alternative is acid leaching followed by selective precipi...

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Main Authors: Rodrigo Souza, Rogério Navarro, Alexandre Vargas Grillo, Eduardo Brocchi
Format: Article
Language:English
Published: Elsevier 2019-01-01
Series:Journal of Materials Research and Technology
Online Access:http://www.sciencedirect.com/science/article/pii/S2238785417305537
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spelling doaj-53a43366dbbf4c03be46731bcf72a9892020-11-25T03:18:31ZengElsevierJournal of Materials Research and Technology2238-78542019-01-0181745751Potassium alum thermal decomposition study under non-reductive and reductive conditionsRodrigo Souza0Rogério Navarro1Alexandre Vargas Grillo2Eduardo Brocchi3Assistant Professor at Pontifícia Universidade Católica do Rio de Janeiro, Chemical and Materials Engineering Department, Rio de Janeiro, Brazil; Corresponding author.Adjunct Professor at Pontifícia Universidade Católica do Rio de Janeiro, Chemical and Materials Engineering Department, Rio de Janeiro, BrazilAdjunct Professor at Instituto Federal do Rio de Janeiro, Physical-Chemistry, Research Group, Nilópolis, BrazilProfessor at Pontifícia Universidade Católica do Rio de Janeiro, Chemical and Materials Engineering Department, Rio de Janeiro, BrazilPotassium sulfate (K2SO4) is a very important compound, mostly used as nutrient for plant growth. Potassium sulfate production can be accomplished through the Mannheim process. For potassium bearing silicate minerals, such as glauconite, one alternative is acid leaching followed by selective precipitation and thermal decomposition of potassium alum (KAl(SO4)2). This chemical process is responsible for the formation of soluble K2SO4 and insoluble Al2O3, which can be later separated after solubilization in water and filtration. In this pyrometallurgical reaction, the temperature control is very important. Through the addition of a reducing agent, the decomposition temperature could be significantly reduced. In the present work, the thermal behavior of synthetic samples of hydrated potassium alum (KAl(SO4)2·12H2O) is appreciated through thermogravimetric analysis (TGA), both in the absence as well as in the presence of a reducing agent (charcoal) under inert atmosphere (nitrogen) and dynamic analysis. The addition of a stoichiometric amount of the reducing agent stimulated considerably the decomposition, which started at a lower temperature in comparison with the pure alum sample. Based on the XRD characterization of selected samples, it is suggested that the decomposition process should happen in at least two stages, with Al2(SO4)3 as one of the intermediate reagents. After full decomposition, only Al2O3 and K2SO4 have been identified, as expected based on thermodynamic simulations. Finally, it was demonstrated that the K2SO4 formed could be totally transferred to aqueous solution after a solubilization carried out at 363 K for two hours; the remaining solid was characterized as pure aluminum oxide (Al2O3). Keywords: Potassium alum, Thermal decomposition, TGA, Charcoal, K2SO4, Al2O3http://www.sciencedirect.com/science/article/pii/S2238785417305537
collection DOAJ
language English
format Article
sources DOAJ
author Rodrigo Souza
Rogério Navarro
Alexandre Vargas Grillo
Eduardo Brocchi
spellingShingle Rodrigo Souza
Rogério Navarro
Alexandre Vargas Grillo
Eduardo Brocchi
Potassium alum thermal decomposition study under non-reductive and reductive conditions
Journal of Materials Research and Technology
author_facet Rodrigo Souza
Rogério Navarro
Alexandre Vargas Grillo
Eduardo Brocchi
author_sort Rodrigo Souza
title Potassium alum thermal decomposition study under non-reductive and reductive conditions
title_short Potassium alum thermal decomposition study under non-reductive and reductive conditions
title_full Potassium alum thermal decomposition study under non-reductive and reductive conditions
title_fullStr Potassium alum thermal decomposition study under non-reductive and reductive conditions
title_full_unstemmed Potassium alum thermal decomposition study under non-reductive and reductive conditions
title_sort potassium alum thermal decomposition study under non-reductive and reductive conditions
publisher Elsevier
series Journal of Materials Research and Technology
issn 2238-7854
publishDate 2019-01-01
description Potassium sulfate (K2SO4) is a very important compound, mostly used as nutrient for plant growth. Potassium sulfate production can be accomplished through the Mannheim process. For potassium bearing silicate minerals, such as glauconite, one alternative is acid leaching followed by selective precipitation and thermal decomposition of potassium alum (KAl(SO4)2). This chemical process is responsible for the formation of soluble K2SO4 and insoluble Al2O3, which can be later separated after solubilization in water and filtration. In this pyrometallurgical reaction, the temperature control is very important. Through the addition of a reducing agent, the decomposition temperature could be significantly reduced. In the present work, the thermal behavior of synthetic samples of hydrated potassium alum (KAl(SO4)2·12H2O) is appreciated through thermogravimetric analysis (TGA), both in the absence as well as in the presence of a reducing agent (charcoal) under inert atmosphere (nitrogen) and dynamic analysis. The addition of a stoichiometric amount of the reducing agent stimulated considerably the decomposition, which started at a lower temperature in comparison with the pure alum sample. Based on the XRD characterization of selected samples, it is suggested that the decomposition process should happen in at least two stages, with Al2(SO4)3 as one of the intermediate reagents. After full decomposition, only Al2O3 and K2SO4 have been identified, as expected based on thermodynamic simulations. Finally, it was demonstrated that the K2SO4 formed could be totally transferred to aqueous solution after a solubilization carried out at 363 K for two hours; the remaining solid was characterized as pure aluminum oxide (Al2O3). Keywords: Potassium alum, Thermal decomposition, TGA, Charcoal, K2SO4, Al2O3
url http://www.sciencedirect.com/science/article/pii/S2238785417305537
work_keys_str_mv AT rodrigosouza potassiumalumthermaldecompositionstudyundernonreductiveandreductiveconditions
AT rogerionavarro potassiumalumthermaldecompositionstudyundernonreductiveandreductiveconditions
AT alexandrevargasgrillo potassiumalumthermaldecompositionstudyundernonreductiveandreductiveconditions
AT eduardobrocchi potassiumalumthermaldecompositionstudyundernonreductiveandreductiveconditions
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