Summary
X-ray photons carry sufficient energy to interact with molecular core-shell’s electrons. Accessible for decades in the energy domain, the resulting core-excited states (CES) can now be observed in the time domain using attosecond (10-18 s) spectroscopy. These states are important as they govern the lineshapes in all x-ray spectroscopies. Here, we propose to first investigate and then manipulate the CES time evolution in solvated biomolecules in order to reveal key chemical information – i.e. solute-solvent interactions, local symmetries and
chiral fields.
CES lifetimes dictate the emission of secondary electrons active in radiotherapy. By observing the effect of solute-solvent interactions on CES we will be able to achieve a better understanding of the first molecular mechanisms of radiotherapy.
CES are also a subtle probe of the absorbing atom’s bonding environment. CES line splittings are lost in conventional x-ray spectroscopy due to homogenous broadening. We developed a technique based on the laser manipulation of CES capable of producing lineshapes up to an order of magnitude below the spectroscopy’s lifetime broadening and revealing core-level splitting. We will employ this approach to observe core-level splitting in solvated amino acids and metalloproteins and will use this new information to reveal the binding geometry of ligands with unprecedented accuracy.
Finally, we will show how one can use nonlinear optics with attosecond pulses to reveal the chirality of the field surrounding sulphur and phosphorus atoms in biological samples. X-ray excitation localizes the point of view on the chiral field to a single atom. This perspective will allow us to examine the chiral landscape near the target atom. Here, chirality due to a single chiral centre will be probed in L-cysteine while the chirality due to the macromolecular arrangement will be measured in DNA helixes.
Our proposal brings attoscience techniques in the investigation field of large solvated systems.
chiral fields.
CES lifetimes dictate the emission of secondary electrons active in radiotherapy. By observing the effect of solute-solvent interactions on CES we will be able to achieve a better understanding of the first molecular mechanisms of radiotherapy.
CES are also a subtle probe of the absorbing atom’s bonding environment. CES line splittings are lost in conventional x-ray spectroscopy due to homogenous broadening. We developed a technique based on the laser manipulation of CES capable of producing lineshapes up to an order of magnitude below the spectroscopy’s lifetime broadening and revealing core-level splitting. We will employ this approach to observe core-level splitting in solvated amino acids and metalloproteins and will use this new information to reveal the binding geometry of ligands with unprecedented accuracy.
Finally, we will show how one can use nonlinear optics with attosecond pulses to reveal the chirality of the field surrounding sulphur and phosphorus atoms in biological samples. X-ray excitation localizes the point of view on the chiral field to a single atom. This perspective will allow us to examine the chiral landscape near the target atom. Here, chirality due to a single chiral centre will be probed in L-cysteine while the chirality due to the macromolecular arrangement will be measured in DNA helixes.
Our proposal brings attoscience techniques in the investigation field of large solvated systems.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101078595 |
| Start date: | 01-10-2023 |
| End date: | 30-09-2028 |
| Total budget - Public funding: | 2 325 590,00 Euro - 2 325 590,00 Euro |
Cordis data
Original description
X-ray photons carry sufficient energy to interact with molecular core-shell’s electrons. Accessible for decades in the energy domain, the resulting core-excited states (CES) can now be observed in the time domain using attosecond (10-18 s) spectroscopy. These states are important as they govern the lineshapes in all x-ray spectroscopies. Here, we propose to first investigate and then manipulate the CES time evolution in solvated biomolecules in order to reveal key chemical information – i.e. solute-solvent interactions, local symmetries andchiral fields.
CES lifetimes dictate the emission of secondary electrons active in radiotherapy. By observing the effect of solute-solvent interactions on CES we will be able to achieve a better understanding of the first molecular mechanisms of radiotherapy.
CES are also a subtle probe of the absorbing atom’s bonding environment. CES line splittings are lost in conventional x-ray spectroscopy due to homogenous broadening. We developed a technique based on the laser manipulation of CES capable of producing lineshapes up to an order of magnitude below the spectroscopy’s lifetime broadening and revealing core-level splitting. We will employ this approach to observe core-level splitting in solvated amino acids and metalloproteins and will use this new information to reveal the binding geometry of ligands with unprecedented accuracy.
Finally, we will show how one can use nonlinear optics with attosecond pulses to reveal the chirality of the field surrounding sulphur and phosphorus atoms in biological samples. X-ray excitation localizes the point of view on the chiral field to a single atom. This perspective will allow us to examine the chiral landscape near the target atom. Here, chirality due to a single chiral centre will be probed in L-cysteine while the chirality due to the macromolecular arrangement will be measured in DNA helixes.
Our proposal brings attoscience techniques in the investigation field of large solvated systems.
Status
SIGNEDCall topic
ERC-2022-STGUpdate Date
31-07-2023
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