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Active HORIZON European Commission

Chiral separation of molecules enabled by enantioselective optical forces in integrated nanophotonic circuits

€3.26M EUR

Funder European Commission
Recipient Organization Universitat Politecnica de Valencia
Country Spain
Start Date Dec 01, 2022
End Date May 31, 2026
Duration 1,277 days
Number of Grantees 7
Roles Participant; Coordinator; Associated Partner
Data Source European Commission
Grant ID 101046961
Grant Description

Separating enantiomers is crucial to produce bio-active molecules, e.g., in early-phase drug discovery.

CHIRALFORCE aims at a radically new strategy to separate enantiometers on chip, using chiral optical forces at silicon-based integrated waveguides.

The present solution of chiral chromatography for this multi-billion market is slow and cumbersome since it requires tailored chemistry for each chiral compound, and relies on large and expensive separation columns.

Instead, CHIRALFORCE envisions cm-length optical circuits integrated with microfluidics for extremely quick, tuneable, and cheap enantiomeric separation.

The underlying mechanism relies on optical forces that are enantioselective, due to interaction of spin-properties of the optical field with the chiral optical polarizability of matter.

These chiral optical forces can be tailored well beyond the possibilities of free-space chiral light through nanophotonic design of strongly confined modes.

Flowing analyte in microfluidic channels along cm-length laser-driven will then result in enantio-separation.The approach to reach our main objectives relies on three main consortium strengths.

First, we will design and synthesize chiral molecules and nanoparticles that will allow us to explore chiral forces regardless of how the chiral polarizability of matter is tuned by the size, shape, and in-built spectroscopic resonances, Next, we will establish the general framework of chiral optical forces on nanoparticles and molecules in liquid environments, leveraging our strength in nanophotonic theory, design and experiment, on chiral/spin-properties of electromagnetic fields.

Finally, we will leverage our experience in nanotechnology to fabricate silicon-based photonic integrated circuits integrated with microfluidics to demonstrate enantiomer separation.

All Grantees

Universiteit Twente; Symeres Netherlands Bv; Universita Degli Studi Di Milano; Universitat Politecnica de Valencia; Stichting Nederlandse Wetenschappelijk Onderzoek Instituten; Tallinna Tehnikaülikool; King's College London

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