Abstract

Chiral molecules and their interactions are critical in a variety of chemical and biological processes. Circular dichroism (CD) is the most widely used optical technique to study chirality, often performed in a solution phase. However, CD has low-efficiency on the order of 0.01–1%. Therefore, there is a growing need to develop high-efficiency chiroptical techniques, especially in gas-phase, to gain background-free in-depth insight into chiral interactions. By using mass spectrometry and strong-field ionization of limonene with elliptically polarized light, we demonstrate an efficient chiral discrimination method that produces a chiral signal of one to two orders of magnitude higher than the conventional CD. The chiral response exhibits a strong dependence on wavelength in the range of 1,300–2,400 nm, where the relative abundance of the ion yields alternates between the two enantiomers. The origin of enhanced enantio-sensitivity in intense laser fields is attributed to two mechanisms that rely on the recollision dynamics in a chiral system: (1) the excited ionic state dynamics mediated either by the laser field or by the recollision process, and (2) non-dipole effects that alter the electron’s trajectories. Our results can serve as a benchmark for testing and developing theoretical tools involving non-dipole effects in strong-field ionization of molecules.

Highlights

  • Chiral molecules and their interactions are critical in a variety of chemical and biological processes

  • C10H16, as a test case, we demonstrate Elliptical dichroism based on recollision enhanced femtosecond laser mass spectrometry (ED-REFLMS)

  • In Photoelectron circular dichroism (PECD), the chiral response is described by the differential cross-section of a photoelectron defined in terms of the angular distribution f­unction[9,29,30]

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Summary

Introduction

Chiral molecules and their interactions are critical in a variety of chemical and biological processes. The left- and right-handed molecules are non-superimposable mirror images of each other, called enantiomers They have identical physical and chemical properties making it difficult to differentiate them. CD measurements are mostly conducted in solution phase, making it difficult to isolate the optical response of the chiral molecule from the influence of solvent-solute ­interactions[13,14] Complementary techniques, such as vibrational circular dichroism and Raman optical ­activity[15], have been used to target the molecules in liquid media by probing the fundamental vibrational bands. Their use in gas-phase studies has been limited. They rely on resonant electronic absorption of one Scientific Reports | (2020) 10:14074

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