Site-specific interrogation of an ionic chiral fragment during photolysis using an X-ray free-electron laser.
Markus IlchenPhilipp SchmidtNikolay M NovikovskiyGregor HartmannPatrick RupprechtRyan N CoffeeArno EhresmannAndreas GallerNick HartmannWolfram HelmlZhirong HuangLudger InhesterAlberto A LutmanJames P MacArthurTimothy J MaxwellMichael MeyerValerija MusicHeinz-Dieter NuhnTimur OsipovDipanwita RayThomas J A WolfSadia BariPeter WalterZheng LiStefan MoellerAndré KniePhilipp V DemekhinPublished in: Communications chemistry (2021)
Short-wavelength free-electron lasers with their ultrashort pulses at high intensities have originated new approaches for tracking molecular dynamics from the vista of specific sites. X-ray pump X-ray probe schemes even allow to address individual atomic constituents with a 'trigger'-event that preludes the subsequent molecular dynamics while being able to selectively probe the evolving structure with a time-delayed second X-ray pulse. Here, we use a linearly polarized X-ray photon to trigger the photolysis of a prototypical chiral molecule, namely trifluoromethyloxirane (C 3 H 3 F 3 O), at the fluorine K-edge at around 700 eV. The created fluorine-containing fragments are then probed by a second, circularly polarized X-ray pulse of higher photon energy in order to investigate the chemically shifted inner-shell electrons of the ionic mother-fragment for their stereochemical sensitivity. We experimentally demonstrate and theoretically support how two-color X-ray pump X-ray probe experiments with polarization control enable XFELs as tools for chiral recognition.