Optical kinks and kink-kink and kink-pulse interactions in resonant two-level media

Novitsky, Denis V.

doi:10.1103/physreva.95.053846

Cited by 5 publications

(2 citation statements)

References 31 publications

(35 reference statements)

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“…It is known that the adiabatically switching waveform (Eq. 4 ) undergoes self-steepening resulting in the kink (shock wave) formation after some distance passed through the resonantly absorbing medium 61 63 . Such a kink is seen in Fig.…”

Section: Resultsmentioning

confidence: 99%

Controlling wave fronts with tunable disordered non-Hermitian multilayers

Novitsky

Lyakhov

Michels

et al. 2021

Sci Rep

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Unique and flexible properties of non-Hermitian photonic systems attract ever-increasing attention via delivering a whole bunch of novel optical effects and allowing for efficient tuning light-matter interactions on nano- and microscales. Together with an increasing demand for the fast and spatially compact methods of light governing, this peculiar approach paves a broad avenue to novel optical applications. Here, unifying the approaches of disordered metamaterials and non-Hermitian photonics, we propose a conceptually new and simple architecture driven by disordered loss-gain multilayers and, therefore, providing a powerful tool to control both the passage time and the wave-front shape of incident light with different switching times. For the first time we show the possibility to switch on and off kink formation by changing the level of disorder in the case of adiabatically raising wave fronts. At the same time, we deliver flexible tuning of the output intensity by using the nonlinear effect of loss and gain saturation. Since the disorder strength in our system can be conveniently controlled with the power of the external pump, our approach can be considered as a basis for different active photonic devices.

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Section: Resultsmentioning

confidence: 99%

Controlling wave fronts with tunable disordered non-Hermitian multilayers

Novitsky

Lyakhov

Michels

et al. 2021

Sci Rep

Self Cite

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“…The further advances include studies of the ever more shorter -few-cycle [48][49][50], subcycle [51], and unipolar [52] -pulses as well as interactions between pulses in resonant media [53,54] resulting in such phenomena as population gratings [55] and diode-like effect [56], among others. On the other hand, the incoherent waveforms with longer characteristic timescales such as incoherent solitons [57] and optical kinks [58,59] can also withstand absorption in resonant media. We also mention the studies of ultrashort pulses [60] and wavefront propagation [61] in disordered resonantly absorbing and amplifying media.…”

Section: Ones)mentioning

confidence: 99%

Tunable virtual gain in resonantly absorbing media

Novitsky¹

2023

Preprint

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Virtual gain refers to the simulation of real light amplification using radiation with exponentially decaying amplitude, so that its complex frequency corresponds to the scattering pole. We theoretically study virtual gain in a two-level resonant medium for different regimes of light-matter interaction depending on the radiation intensity. We show that virtual gain at the pole can be most clearly observed for low intensities, when the medium is absorbing, in contrast to the saturated medium at high intensities. The efficiency of virtual gain can be tuned with the light intensity and can be controlled dynamically through the population inversion of the medium. Our results show that resonantly absorbing media paradoxically mimics gain-like response, which admit a number of related phenomena and methods to mold both optical signals and material properties without relying on instability-prone gain media.

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Tunable virtual gain in resonantly absorbing media

Novitsky

2023

Phys. Rev. A

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Optical kinks and kink-kink and kink-pulse interactions in resonant two-level media

Cited by 5 publications

References 31 publications

Controlling wave fronts with tunable disordered non-Hermitian multilayers

Controlling wave fronts with tunable disordered non-Hermitian multilayers

Tunable virtual gain in resonantly absorbing media

Tunable virtual gain in resonantly absorbing media

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