Structural Dynamics (Jan 2021)

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

  • B. Belsa,
  • K. Amini,
  • X. Liu,
  • A. Sanchez,
  • T. Steinle,
  • J. Steinmetzer,
  • A. T. Le,
  • R. Moshammer,
  • T. Pfeifer,
  • J. Ullrich,
  • R. Moszynski,
  • C. D. Lin,
  • S. Gräfe,
  • J. Biegert

DOI
https://doi.org/10.1063/4.0000046
Journal volume & issue
Vol. 8, no. 1
pp. 014301 – 014301-8

Abstract

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Visualizing molecular transformations in real-time requires a structural retrieval method with Ångström spatial and femtosecond temporal atomic resolution. Imaging of hydrogen-containing molecules additionally requires an imaging method 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-Ångström 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 ( Φ HNH = 107 °) to planar ( Φ HNH = 120 °) structure in approximately 8 femtoseconds. Using LIED, we retrieve a near-planar ( Φ 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.