Summary
The production of cement is predicted to account for 25% of anthropogenic CO2 emissions by 2025. There is a need to produce novel reduced CO2 cement materials to reduce global carbon emissions. This project aims to characterise a novel silicate glass material for the production of reduced CO2 cement. The novel silicate glass utilises nanoscale phase separations to enhance the reactivity. The goal of this work is two fold: first, to systematically study the tuneability of the reactivity and nanoscale phase separations in the silicate glass and second, to characterise the glass and cement samples with advanced nuclear magnetic resonance (NMR) methods. First, enhanced reactivity of glasses has previously been observed but has not been systematically studied. The composition of the silicate glass will be changed to study the tuneability of the reactivity and phase separations. The studies will be conducted using standard experiments such as solid state NMR for studying the chemical bonding and scanning electron microscopy (SEM) for visualising phase separations. The results of these studies will contribute to knowledge in glass science and produce a reduced CO2 cement material. Second, the glass and cement will be studied with advanced NMR methods. NMR is a research tool that has previously proven successful in studying the pore structures of glasses and cements. This proposal will utilise breakthroughs in NMR technology, ultrafast Laplace NMR (LNMR) and hyperpolarisaton, to gain further insight into the microstructure of samples. Ultrafast LNMR enhances the time sensitivity of LNMR scans by 2-4 magnitudes and reduces scan time by 1-2 orders of magnitude. Hyperpolarisation enhances the sensitivity of NMR scans by 2-5 orders of magnitude. Together these methods will be used to enhance the time resolution and sensitivity of NMR methods. The results of these studies will produce new NMR methodology and provide novel data in glass and cement samples.
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| Web resources: | https://cordis.europa.eu/project/id/896824 |
| Start date: | 01-09-2021 |
| End date: | 31-08-2023 |
| Total budget - Public funding: | 190 680,96 Euro - 190 680,00 Euro |
Cordis data
Original description
The production of cement is predicted to account for 25% of anthropogenic CO2 emissions by 2025. There is a need to produce novel reduced CO2 cement materials to reduce global carbon emissions. This project aims to characterise a novel silicate glass material for the production of reduced CO2 cement. The novel silicate glass utilises nanoscale phase separations to enhance the reactivity. The goal of this work is two fold: first, to systematically study the tuneability of the reactivity and nanoscale phase separations in the silicate glass and second, to characterise the glass and cement samples with advanced nuclear magnetic resonance (NMR) methods. First, enhanced reactivity of glasses has previously been observed but has not been systematically studied. The composition of the silicate glass will be changed to study the tuneability of the reactivity and phase separations. The studies will be conducted using standard experiments such as solid state NMR for studying the chemical bonding and scanning electron microscopy (SEM) for visualising phase separations. The results of these studies will contribute to knowledge in glass science and produce a reduced CO2 cement material. Second, the glass and cement will be studied with advanced NMR methods. NMR is a research tool that has previously proven successful in studying the pore structures of glasses and cements. This proposal will utilise breakthroughs in NMR technology, ultrafast Laplace NMR (LNMR) and hyperpolarisaton, to gain further insight into the microstructure of samples. Ultrafast LNMR enhances the time sensitivity of LNMR scans by 2-4 magnitudes and reduces scan time by 1-2 orders of magnitude. Hyperpolarisation enhances the sensitivity of NMR scans by 2-5 orders of magnitude. Together these methods will be used to enhance the time resolution and sensitivity of NMR methods. The results of these studies will produce new NMR methodology and provide novel data in glass and cement samples.Status
TERMINATEDCall topic
MSCA-IF-2019Update Date
28-04-2024
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