Electronic Quantum Coherence in Glycine Probed with Femtosecond X-rays

Structural changes in nature and technology are driven by charge carrier motion. A process such as solar-energy conversion can be more efficient, if energy transfer and charge motion proceeds along well-defined quantum mechanical pathways keeping the coherence and minimizing dissipation [1-5]. The open question is: do long-lived electronic quantum coherences exist in complex molecules [6-12]? Here, we use x-rays to create and monitor electronic wave packets in an amino acid. The outgoing photoelectron wave leaves behind a positive charge formed by a superposition of quantum mechanical eigenstates. Delayed x-ray pulses track the induced electronic coherence in two different ways. On the one hand, by exciting core electrons into the transient electron hole states the subsequent Auger decay serves as a marker of electron hole survival. On the other hand, photoelectron emission from sequential double photoionization processes monitors opposite quantum phases of non-stationary electron hole states depending on their binding energy. The observed sinusoidal modulation of the detected electron yield as a function of time with a phase-jump at ~246 eV kinetic energy of electrons clearly demonstrates that electronic quantum coherence is preserved for at least 25 femtoseconds in this molecule of biological relevance. The experimental results are in agreement with advanced ab-initio simulations.