Summary
Chiral molecules exist as two forms, called enantiomers, which are mirror images of each other but which are not superimposable. Living organisms are built upon chiral elementary blocks. Biological processes can thus be extremely sensitive to chirality. Two enantiomers can have different smells or tastes. More critically, a chiral molecule can have healing properties while its mirror image is a poison. This makes the measurement of enantiomeric excess (EE), which quantifies the relative composition of the two images in a mixture, crucial for many industrial sectors: fragrance and food industry, pharmaceutics, agrochemistry. To improve product quality, lower health risks, and optimize processes to reduce chemical waste, it would be necessary to monitor EE continuously. Yet, this task is currently impossible because there is no fast and accurate enough EE measurement method. The FastEE project aims at solving this issue by using a new physical process which is extremely sensitive to chirality. By investigating the photoionization of chiral molecules by elliptically polarized light, we found out that the angular distribution of the ejected electrons carried rich information on the ionized molecules as well as their enantiomeric purity. Continuously modulating the ellipticity of the ionizing radiation while recording images of the photoelectron distribution enables the chemical composition and EE of mixtures to be followed in in real-time.
FastEE aims at:
(i) designing a demonstrator instrument using this method, optimized for an applicative environment,
(ii) optimizing the method for the accurate analysis of complex chiral mixtures in real-time,
(iii) investigating transfer and commercialization strategies.
After completion of the three phases, we will be able to offer a new solution (instrument and methodology) for chiral analysis, enabling fast and continuous measurements with excellent accuracy - which is not possible with current technologies.
FastEE aims at:
(i) designing a demonstrator instrument using this method, optimized for an applicative environment,
(ii) optimizing the method for the accurate analysis of complex chiral mixtures in real-time,
(iii) investigating transfer and commercialization strategies.
After completion of the three phases, we will be able to offer a new solution (instrument and methodology) for chiral analysis, enabling fast and continuous measurements with excellent accuracy - which is not possible with current technologies.
Unfold all
/
Fold all
More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/963967 |
| Start date: | 01-01-2021 |
| End date: | 30-06-2022 |
| Total budget - Public funding: | - 150 000,00 Euro |
Cordis data
Original description
Chiral molecules exist as two forms, called enantiomers, which are mirror images of each other but which are not superimposable. Living organisms are built upon chiral elementary blocks. Biological processes can thus be extremely sensitive to chirality. Two enantiomers can have different smells or tastes. More critically, a chiral molecule can have healing properties while its mirror image is a poison. This makes the measurement of enantiomeric excess (EE), which quantifies the relative composition of the two images in a mixture, crucial for many industrial sectors: fragrance and food industry, pharmaceutics, agrochemistry. To improve product quality, lower health risks, and optimize processes to reduce chemical waste, it would be necessary to monitor EE continuously. Yet, this task is currently impossible because there is no fast and accurate enough EE measurement method. The FastEE project aims at solving this issue by using a new physical process which is extremely sensitive to chirality. By investigating the photoionization of chiral molecules by elliptically polarized light, we found out that the angular distribution of the ejected electrons carried rich information on the ionized molecules as well as their enantiomeric purity. Continuously modulating the ellipticity of the ionizing radiation while recording images of the photoelectron distribution enables the chemical composition and EE of mixtures to be followed in in real-time.FastEE aims at:
(i) designing a demonstrator instrument using this method, optimized for an applicative environment,
(ii) optimizing the method for the accurate analysis of complex chiral mixtures in real-time,
(iii) investigating transfer and commercialization strategies.
After completion of the three phases, we will be able to offer a new solution (instrument and methodology) for chiral analysis, enabling fast and continuous measurements with excellent accuracy - which is not possible with current technologies.
Status
CLOSEDCall topic
ERC-2020-POCUpdate Date
27-04-2024
Images
No images available.
Geographical location(s)
