Gring, M., Gerlich, S., Eibenberger, S., Nimmrichter, S., Berrada, T., Arndt, M., Ulbricht, H., Hornberger, K., Müri, M., Mayor, M., Böckmann, M., & Doltsinis, N. (2010). Influence of conformational molecular dynamics on matter wave interferometry. Physical Review A, 81(031604). https://doi.org/10.1103/physreva.81.031604
We investigate the influence of thermally activated internal molecular dynamics on the phase shifts of matter
waves inside a molecule interferometer. While de Broglie physics generally describes only the center-of-mass
motion of a quantum object, our experiment demonstrates that the translational quantum phase is sensitive to
dynamic conformational state changes inside the diffracted molecules. The structural flexibility of tailor-made
organic particles is sufficient to admit a mixture of strongly fluctuating dipole moments. These modify the
electric susceptibility and through this the quantum interference pattern in the presence of an external electric
field. Detailed molecular dynamics simulations combined with density-functional theory allow us to quantify the
time-dependent structural reconfigurations and to predict the ensemble-averaged square of the dipole moment
which is found to be in good agreement with the interferometric result. The experiment thus opens a different
perspective on matter wave interferometry, as we demonstrate here that it is possible to collect structural
information about molecules even if they are delocalized over more than 100 times their own diameter.
en
Research Areas:
Quantum Many-Body Systems: 40% Design and Engineering of Quantum Systems: 30% Quantum Metrology and Precision Measurements: 30%