Abstract:
The newborn phenomenon of temporal cloaking is investigated under the
e®ects of Doppler broadening and Kerr nonlinearity in di®erent atomic me-
dia. The optical properties of these media are manipulated in such a manner
that a time gap is created in the propagating probe light where events or
information can be transmitted undetected. To create the cloaking time
gap, the enhanced subluminal and superluminal behaviors of the probe ¯eld
are focused. The opened temporal gap is closed by an inverse process that
involves reverse modi¯cation of the optical properties of the medium. Ini-
tially, we consider a ¯ve-level M-type atomic con¯guration of rubidium. The
concept of Doppler broadening is introduced along with the superposition of
the double resonant ¯elds in the system. Phase shift variations are caused
in the medium which result into a signi¯cant delay and advancement of the
probe pulse. The delay and advancement times lead to the generation of a
time hole for concealing information in the temporal domain. A microsecond
time gap is attained without signi¯cant distortion in the pulse shape. The
time gap is further increased to several orders of microseconds with increase
in the Doppler width. Next, we investigate propagation of the light pulse
in a four-level Doppler broadened sodium atomic system. The possibility of
creating a temporal gap is discussed on the basis of spectral hole burning in
the system. The probe pulse is observed to delay in the hole burning region
while it advances in the nearest neighboring region. A cloaking time gap
of the order of microseconds is achieved in the slow and fast light regime.
The time gap is modi¯ed with the inverse Doppler e®ect. The time gap can
also be tuned and modi¯ed with the strengths of the coupling ¯elds, if the
Doppler width is kept constant in the system. Finally, we extend our studies
to the three-level rubidium atomic system. The pulse delay and advancement
vi
times are observed at speci¯c system parameters in the presence of self-Kerr
¯eld e®ect. The delay and advance times are enhanced with increase in the
intensity of self-Kerr ¯eld. A cloaking time gap of the order of nanosecond
is created in the observed fast and slow light. Increase of the time gap is
observed with increase in the intensity of self-Kerr nonlinearity. The time
gap is enhanced to several orders of nanosecond, su±cient to hide any prac-
tical event. The time gaps are closed by reverse manipulation of the optical
properties. Our results may contribute to strengthening the idea of hiding
events in successive temporal gaps for achieving enhanced security of the
communication systems.