Interplay of classical and quantum dynamics in a thermal ensemble of atoms

In a thermal ensemble of atoms driven by coherent fields, how does evolution of quantum superposition compete with classical dynamics of optical pumping and atomic diffusion? Is it optical pumping that first prepares a thermal ensemble, with coherent superposition developing subsequently or is it th...

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Bibliographic Details
Published in:New journal of physics 2016-05, Vol.18 (5), p.53022
Main Authors: Laskar, Arif Warsi, Singh, Niharika, Mukherjee, Arunabh, Ghosh, Saikat
Format: Article
Language:English
Subjects:
atomic coherence
Coherence
Computer simulation
Diffusion
Diffusion pumps
Dynamics
electromagnetically induced transparency
Evolution
half-cycle Rabi flop
interplay of coherence and incoherent processes
lasing without inversion
light-atom interaction
Mathematical models
Open systems
Optical pumping
Physics
Quantum mechanics
Rubidium
Steady state
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Summary:In a thermal ensemble of atoms driven by coherent fields, how does evolution of quantum superposition compete with classical dynamics of optical pumping and atomic diffusion? Is it optical pumping that first prepares a thermal ensemble, with coherent superposition developing subsequently or is it the other way round: coherently superposed atoms driven to steady state via optical pumping? Using a stroboscopic probing technique, here we experimentally explore these questions. A 100 ns pulse is used to probe an experimentally simulated, closed three-level, Λ-like configuration in rubidium atoms, driven by strong coherent (control) and incoherent fields. Temporal evolution of probe transmission shows an initial overshoot with turn-on of control, resulting in a scenario akin to lasing without inversion. The corresponding rise time is dictated by coherent dynamics, with a distinct experimental signature of half-cycle Rabi flop in a thermal ensemble of atoms. Our results indicate that, in fact, optical pumping drives the atoms to a steady state in a significantly longer time-scale that sustains superposed dark states. Eventual control turn-off leads to a sudden fall in transmission with an ubiquitous signature for identifying closed and open systems. Numerical simulations and toy-model predictions confirm our claims. These studies reveal new insights into a rich and complex dynamics associated with atoms in thermal ensemble, which are otherwise absent in state-prepared, cold atomic ensembles.
ISSN:1367-2630
1367-2630
DOI:10.1088/1367-2630/18/5/053022