Pretreated magnesite as a source of low-cost magnesium for producing struvite from urine in Nepal

Struvite is a solid phosphorus fertilizer that can be recovered easily from source-separated urine by dosing it with a soluble form of magnesium. The process is simple and low-cost, however, previous studies have shown that the cost of magnesium in low-income countries is crucial to the viability an...

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Published in:The Science of the total environment 2016-01, Vol.542 (Pt B), p.1155-1161
Main Authors: Krähenbühl, Manuel, Etter, Bastian, Udert, Kai M.
Format: Article
Language:English
Subjects:
Calcination
Carbon dioxide
Chemical Precipitation
Crystallites
Dissolution
Fertilizers
Green Chemistry Technology - methods
Magnesite
Magnesium
Magnesium - chemistry
Magnesium ammonium phosphate (MAP)
Magnesium carbonate
Magnesium Compounds - chemistry
Nepal
Nutrient recovery
Optimization
Phosphates - chemistry
Struvite
Struvite precipitation
Urine
Urine separation
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cited_by cdi_FETCH-LOGICAL-c437t-b8880ed8fc7817991d63f23ee7e1fd688d894b9fbf7b16c90757446c4d9b6e853
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container_end_page 1161
container_issue Pt B
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container_title The Science of the total environment
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creator Krähenbühl, Manuel
Etter, Bastian
Udert, Kai M.
description Struvite is a solid phosphorus fertilizer that can be recovered easily from source-separated urine by dosing it with a soluble form of magnesium. The process is simple and low-cost, however, previous studies have shown that the cost of magnesium in low-income countries is crucial to the viability and implementation of struvite precipitation. Literature has proposed producing inexpensive magnesium locally by making magnesium oxide from magnesite. This paper aimed to investigate whether process requirements, costs, and environmental impacts would make this process viable for magnesium production in decentralized settings. Magnesite samples were calcined at temperatures between 400°C and 800°C and for durations between 0.5h and 6h. The release of magnesium was tested by dissolution in phosphate-depleted urine. The optimal processing conditions were at 700°C for 1h: magnesite conversion was incomplete at lower temperatures, and the formation of large crystallites caused a decrease in solubility at higher temperatures. The narrow optimal range for magnesium production from magnesite requires reliable process control. Cost estimations for Nepal showed that using local magnesite would provide the cheapest source of magnesium and that CO2 emissions from transport and production would be negligible compared to Nepal's overall CO2 emissions. [Display omitted] •Calcined magnesite rock can provide soluble MgO for struvite precipitation.•Heating at 700°C for 1h is optimal for calcination of Nepalese magnesite.•During calcination, temperature control is crucial for the production of soluble MgO.•MgO from calcined magnesite can be an inexpensive local magnesium source for Nepal.
doi_str_mv 10.1016/j.scitotenv.2015.08.060
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The process is simple and low-cost, however, previous studies have shown that the cost of magnesium in low-income countries is crucial to the viability and implementation of struvite precipitation. Literature has proposed producing inexpensive magnesium locally by making magnesium oxide from magnesite. This paper aimed to investigate whether process requirements, costs, and environmental impacts would make this process viable for magnesium production in decentralized settings. Magnesite samples were calcined at temperatures between 400°C and 800°C and for durations between 0.5h and 6h. The release of magnesium was tested by dissolution in phosphate-depleted urine. The optimal processing conditions were at 700°C for 1h: magnesite conversion was incomplete at lower temperatures, and the formation of large crystallites caused a decrease in solubility at higher temperatures. The narrow optimal range for magnesium production from magnesite requires reliable process control. 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1879-1026
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source Elsevier
subjects Calcination
Carbon dioxide
Chemical Precipitation
Crystallites
Dissolution
Fertilizers
Green Chemistry Technology - methods
Magnesite
Magnesium
Magnesium - chemistry
Magnesium ammonium phosphate (MAP)
Magnesium carbonate
Magnesium Compounds - chemistry
Nepal
Nutrient recovery
Optimization
Phosphates - chemistry
Struvite
Struvite precipitation
Urine
Urine separation
title Pretreated magnesite as a source of low-cost magnesium for producing struvite from urine in Nepal
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