Developmental Study of a Low-pH Magnesium Phosphate Cement for Environmental Applications

Developmental Study of a Low-pH Magnesium Phosphate Cement for Environmental Applications

This paper presents a laboratory investigation into the development of a low-pH magnesium phosphate-based cement for use in in-situ stabilisation/solidification systems, as a more effective alternative to Portland cement. The idea is to develop a cement-based binder with a low enough pH to facilitat...

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Bibliographic Details
Published in:Environmental technology Vol. 28; no. 12; pp. 1387 - 1401
Main Authors: Iyengar, S. R., Al-Tabbaa, Abir
Format: Journal Article
Language:English
Published: London Taylor & Francis Group 01-12-2007
Selper
Subjects:
Applied sciences
CHEMICALLY BONDED CERAMICS
Construction Materials
Exact sciences and technology
General treatment and storage processes
Hydrogen-Ion Concentration
LOW PH CEMENT
Magnesium Compounds - chemistry
Magnesium Oxide - chemistry
MAGNESIUM PHOSPHATE CEMENTS
Microscopy, Electron, Scanning
Phosphates - chemistry
Pollution
Potassium Compounds - chemistry
WASTE MANAGEMENT
Wastes
X-Ray Diffraction
British Isles
Biodegradation
Phosphates
chemically bonded ceramics
Impurity
Pollutant behavior
Waste treatment
In situ
Reaction product
Volume expansion
Binders
Portland cement
Solidification
Waste management
Low pH cement
pH
magnesium phosphate cements
Microstructure
Ceramic materials
Strength
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Summary:This paper presents a laboratory investigation into the development of a low-pH magnesium phosphate-based cement for use in in-situ stabilisation/solidification systems, as a more effective alternative to Portland cement. The idea is to develop a cement-based binder with a low enough pH to facilitate biodegradation in combination with stabilisation/solidification processes. Potassium dihydrogen orthophosphate was selected as the phosphate source, dead-burned magnesia as the magnesium source and boric acid as the retarder. The range of mixes were tested primarily on their pH development which was found to be in the range of 6-9.5 for a magnesia to phosphate ratio range of 1:1 to 1:5. The testing revealed a dense microstructure, high early-age strength development and low volume expansion of the developed cement. Observed fracturing of some of the cured cement samples has been related to the curing conditions and the impurities present in the magnesia. On the basis of microstructural examination, observed white crystalline deposits on cured samples are likely to be a reaction product of magnesia and potassium dihydrogen phosphate.
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ISSN:0959-3330
1479-487X
DOI:10.1080/09593332808618899