Laser-induced electron diffraction of the ultrafast umbrella motion in ammonia

Abstract

Visualizing molecular transformations in real-time requires a structural retrieval method with ngstr\"om spatial and femtosecond temporal atomic resolution. Imaging of hydrogen-containing molecules additionally requires an imaging method that is sensitive to the atomic positions of hydrogen nuclei, with most methods possessing relatively low sensitivity to hydrogen scattering. Laser-induced electron diffraction (LIED) is a table top technique that can image ultrafast structural changes of gas-phase polyatomic molecules with sub-ngstr\"om and femtosecond spatiotemporal resolution together with relatively high sensitivity to hydrogen scattering. Here, we image the umbrella motion of an isolated ammonia molecule (NH3) following its strong field ionization. Upon ionization of a neutral ammonia molecule, the ammonia cation (NH3+) undergoes an ultrafast geometrical transformation from a pyramidal (HNH = 107 ) to planar (HNH=120) structure in approximately 8 femtoseconds. Using LIED, we retrieve a near-planar (HNH=117 5) field-dressed NH3+ molecular structure 7.8-9.8 femtoseconds after ionization. Our measured field-dressed NH3+ structure is in excellent agreement with our calculated equilibrium field dressed structure using quantum chemical ab initio calculations.