New research from the Niels Bohr Institute shows that cement made with waste ash from sugar production is stronger than ordinary cement. The research shows that the ash helps to bind¹ water in the cement so that it is stronger, can withstand higher pressure and crumbles³（弄碎） less. At the same time, energy is saved and pollution from cement production is reduced. The results are published in the scientific journal, Scientific Reports.

 

Cement is composed of chalk and clay, which are mixed together and heated at high temperatures in a cement kiln⁴（水泥窑）. The mixture is then crushed into a powder. When the cement powder is mixed with water a chemical process takes place, which causes the cement mixture to harden. Cement is used as a building material throughout the world.

 

In some countries where sugar cane⁵ is grown, agricultural waste product from sugar production has been added to the cement mixture for many years. Once the sugar has been extracted from the sugar can you are left with a lot of fibre waste, which is used as fuel for energy production. From the energy production you get a lot of ash, which needs to be disposed of. In some countries, like Cuba and Brazil, the ash is added into cement mixtures.

 

"I have been studying cement using quasi-elastic neutron⁶ scattering⁸ for several years and researchers from Brazil asked whether I wanted to analyse samples of cement mixed with waste products in the form of sugar cane ash. I decided⁹ to say yes to the project, which aimed to investigate the properties on a nano-scale and map the mobility¹⁰ of water in the cement. The quality and strength of cement is directly related to how much of the water is chemically bonded¹¹. The more the water can move around, the worse it is for the strength and durability," explains Heloisa Bordallo, who does research in nanophysics at the Niels Bohr Institute at the University of Copenhagen.

 

 

Heloisa Bordallo was sent a number of cement samples from Brazil. The samples contained varying amounts of ash from sugar can production. Their innermost dynamics¹² were then examined. This took place at the ISIS facility in the UK. The samples were placed in an instrument where they were bombarded by neutrons¹³.

 

"Using neutron scattering, we can see how the water inside the sample moves. Neutrons are shot into the sample and when neutrons hit the water's hydrogen atoms, they interact and the neutrons scatter⁷ and are picked up by the detectors¹⁴. We repeat this for several hours and by analysing the data we can determine how the water inside the sample is moving and also determine its local environment," explains Johan Jacobsen, who performed the experiments as part of his thesis for the graduate programme in physics at the Niels Bohr Institute.

 

The experiments showed that the cement mixed with approx. 20 percent ash had good properties. The water the cement pores was bound to the ash and moved around less. This explains why the ash cement is stronger, can withstand higher pressure and will crumble² less.

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