Add to ORKGThe paper presents the selected results of the thermal decomposition of natural magnesite for preparation of active MgO. At the temperature of selective decomposition of magnesite intermediate phases exhibiting enhanced reactivity and low mechanical stability are formed. Evolution of carbon dioxide is accompanied by decrepitation of active magnesia. The selective decomposition and the accompanying decrepitation of the solid may be conveniently used as a way of enriching the chemically active magnesia by simple screening. Magnesia is accumulated in the undersize fraction, whereas undecomposed calcium carbonate and silica remain in the oversize fractions
391-397Basic data on leaching of magnesite (MgCO3) with sulphuric acid are of interest from the poin...
Magnesite precipitation from aqueous solution, despite conditions of supersaturation, is kinetically...
This paper investigates the behavior of calcined powder made of natural magnesite and natural steati...
Thermal decomposition of magnesite is investigated by using a TG–MS. Different kinetic methods inclu...
The X-ray line broadening technique was used to calculate the grain size of MgO at 1023, 1123, 1223 ...
AbstractInvestigations of the changes of structure, specific surface and true density of following h...
The performance of magnesium oxide-based cements and expansion agent closely relates to the reactivi...
135-138In this study, magnesite mineral was first calcinated between 800-1100 K for an hour and diss...
The study describes a new wet chemical technique, termed ANM, for the isolation of secondary phases ...
The thermal decomposition process of basic magnesium carbonate was investigated. Firstly, Basic magn...
A laboratory method was designed and verified that allows for the testing of alkaline, magnesite-bas...
Thermal decomposition kinetics of magnesite were investigated using non-isothermal TG-DSC technique ...
WOS: 000399643200016This paper deals with the current magnesite concentration technology and upgradi...
Magnesium carbonate powders are essential in the manufacture of basic refractories capable of withst...
A mixed-mineralogy talc mine tailing (MT) fraction consisting of 80% ferroan magnesite (MgCO3) was s...
391-397Basic data on leaching of magnesite (MgCO3) with sulphuric acid are of interest from the poin...
Magnesite precipitation from aqueous solution, despite conditions of supersaturation, is kinetically...
This paper investigates the behavior of calcined powder made of natural magnesite and natural steati...
Thermal decomposition of magnesite is investigated by using a TG–MS. Different kinetic methods inclu...
The X-ray line broadening technique was used to calculate the grain size of MgO at 1023, 1123, 1223 ...
AbstractInvestigations of the changes of structure, specific surface and true density of following h...
The performance of magnesium oxide-based cements and expansion agent closely relates to the reactivi...
135-138In this study, magnesite mineral was first calcinated between 800-1100 K for an hour and diss...
The study describes a new wet chemical technique, termed ANM, for the isolation of secondary phases ...
The thermal decomposition process of basic magnesium carbonate was investigated. Firstly, Basic magn...
A laboratory method was designed and verified that allows for the testing of alkaline, magnesite-bas...
Thermal decomposition kinetics of magnesite were investigated using non-isothermal TG-DSC technique ...
WOS: 000399643200016This paper deals with the current magnesite concentration technology and upgradi...
Magnesium carbonate powders are essential in the manufacture of basic refractories capable of withst...
A mixed-mineralogy talc mine tailing (MT) fraction consisting of 80% ferroan magnesite (MgCO3) was s...
391-397Basic data on leaching of magnesite (MgCO3) with sulphuric acid are of interest from the poin...
Magnesite precipitation from aqueous solution, despite conditions of supersaturation, is kinetically...
This paper investigates the behavior of calcined powder made of natural magnesite and natural steati...