Ultrafast Proton Transfer Driven by a Femtosecond Strong-Field Laser Pulse

Alexei Markevitch; Dmitri Romanov; Stanley Smith; Robert Levis

Ultrafast Proton Transfer Driven by a Femtosecond Strong-Field Laser Pulse

POSTER

Abstract

Kinetic energy distributions of protons ejected from a polyatomic molecule, anthraquinone, subjected to 60~fs, 800~nm laser pulses of intensity between 0.2 and 4.0x10\^{}14~W/cm\^{}2, reveal field-driven restructuring of the molecule (intramolecular proton migration) prior to its Coulomb explosion. Model calculations demonstrate that proton migrates into a field-dressed metastable potential energy minimum. Isomerization mediated by strong field is an important novel phenomenon in coupling of polyatomic molecules with intense laser pulses.

Authors

Alexei Markevitch

Temple University, Department of Chemistry
Dmitri Romanov

Dept. of Physics, Center for Advanced Photonics Research, Temple University, Temple University,Department of Physics
Stanley Smith

Wayne State University, Detroit, MI, Wayne State University, Department of Chemistry
Robert Levis

Temple University, Dept. of Chemistry, Center for Advanced Photonics Research, Temple University, Temple University, Department of Chemistry