We experimentally verified our prior theoretical work [J. Opt. Soc. Am. B 39, 3012 (2022)] by
employing matter-wave interference to measure the ultranarrow momentum width of an …

We analyze the statistical properties of radiative transitions for a molecular system
possessing discrete, equally spaced, energy levels, interacting with thermal radiation at …

The propagation of light in moving media is dragged by atomic motion. The light-drag effect
can be dramatically enhanced by reducing the group velocity with electromagnetically …

We propose a method to characterize the ultra-narrow momentum distribution of atomic
gases by employing a standing-wave light-pulse sequences beam splitter. The mechanism …

In this letter, we apply an optical setup to simulate the coherent evolution of an atomic
wavepacket under the action of a standing-wave optical pulse sequence. Predicted …

A distributional route to Gaussianity, associated with the concept of Conservative Mixing
Transformations (CMT) in ensembles of random vector-valued variables, is proposed. This …

We explore the dynamics of open quantum systems in both equilibrium and nonequilibrium
situations. Our focus lies on the quantum-optical dispersion interaction between a …

Atomic diffraction is the central concept of matter-wave interferometers, which provide the
opportunity of high-precision rotation and acceleration sensing. Ultracold atoms are the …

We experimentally measured the ultra-narrow momentum width of an optical trapped Bose-
Einstein condensate (BEC) in situ based on matter-wave interference, which validates our …

Atom interferometric sensors can enable extremely precise measurements of inertial motion
and external fields by manipulating and interfering atomic states using pulses of laser light …