Observation of Bloch oscillations in complex PT-symmetric photonic lattices

Wimmer, Martin; Miri, Mohammed-Ali; Christodoulides, Demetrios N.; Peschel, Ulf

doi:10.1038/srep17760

Cited by 127 publications

(121 citation statements)

References 27 publications

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“…More importantly, the gain and loss coefficients can be adjusted more independently, which will be easier to control the gain, loss, and coupling coefficients to realize the PT‐symmetric condition and study related effects. Furthermore, by taking advantage of the large parametric space in multi‐level atomic configurations, such newly demonstrated periodic gain/loss optical lattices can provide a more flexible platform to investigate the diverse effects such as solitons in PT‐symmetric nonlinear lattices and unidirectional light transport resulting from the interplay between non‐Hermitian Hamiltonian and nonlinear effects, and various beam dynamical properties such as non‐Hermitian Bloch oscillation predicted in non‐Hermitian optical lattices. Also, this EIT‐based scheme can be extended to various atom‐like solid materials, and hopefully create useful PT‐symmetric optical devices.…”

Section: Resultsmentioning

confidence: 99%

“…So far, experimental realizations of periodically arranged PT‐symmetric potentials have been limited only to a few optical settings, such as a time‐domain lattice realized in a network of coupled gain/loss fiber loops, and an optical waveguide array with a lossy (without gain) background . The known exact PT‐symmetric optical lattice with spatially periodic gain and loss channels was realized in a four‐level N ‐type atomic configuration .…”

Section: Introductionmentioning

confidence: 99%

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Parity‐Time‐Symmetric Optical Lattice with Alternating Gain and Loss Atomic Configurations

Zhang

Yang

Feng

et al. 2018

Laser & Photonics Reviews

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Since the periodic parity‐time (PT)‐symmetric potential can possess unique properties compared to a single PT cell (with only two coupled components), various schemes have been proposed to realize PT symmetry in optical lattices. Here, a PT‐symmetric optical lattice is experimentally constructed with simultaneous gain and loss in an atomic medium. The gain and loss arrays are created in the four‐level N‐type configurations excited by spatially alternating strong and weak pump fields, respectively, which do not require discrete diffractions and can be realized more easily with more relaxed operating conditions. Also, the gain and loss coefficients can be modified independently. The dynamical behaviors of the system are investigated by measuring the phase difference between two adjacent gain and loss channels. The demonstrated PT‐symmetric lattice with easy accessibility and better tunability shows obvious advantages in exploiting more peculiar properties and great improvements in practical applications of periodic PT‐symmetric potentials.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Parity‐Time‐Symmetric Optical Lattice with Alternating Gain and Loss Atomic Configurations

Zhang

Yang

Feng

et al. 2018

Laser & Photonics Reviews

View full text Add to dashboard Cite

show abstract

“…A number of important effects have been demonstrated in SPLs, including random walks of single particles 11 , Bloch oscillations and unidirectional invisibility associated with parity-time symmetry 12, 15 , scattering on defect states 16 , and diametric drive acceleration 17 . Furthermore, SPLs are naturally suitable for observation of Anderson localization, since any degree of disorder can be introduced through programmable electro-optic phase-modulation of individual propagating pulses at specific time slots of the lattice.…”

Section: Introductionmentioning

confidence: 99%

Anderson localization in synthetic photonic lattices

Vatnik

Tikan

Onishchukov

et al. 2017

Sci Rep

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Synthetic photonic lattices provide unique capabilities to realize theoretical concepts emerging in different fields of wave physics via the utilization of powerful photonic technologies. Here we observe experimentally Anderson localization for optical pulses in time domain, using a photonic mesh lattice composed of coupled fiber loops. We introduce a random potential through programmed electro-optic pulse phase modulation, and identify the localization features associated with varying degree of disorder. Furthermore, we present a practical approach to control the band-gap width in photonic lattices by varying the coupling between the fiber loops, and reveal that the strongest degree of localization is limited and increases in lattices with wider band-gaps. Importantly, this opens a possibility to enhance or reduce the effect of disorder and associated localization of optical pulses.

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“…Although the nonHermitian Hamiltonian considered in [20] is PT symmetric, the total power was observed to be changed in time. In the experiment [21], pseudo-Hermitian wave packet propagation with a vanishing net increase in power was observed by controlling the period of the Bloch oscillation in a global and local PT symmetric mesh lattice. A resonant restoration of PT symmetry and secondary emissions, which occurs each time the wave packet passes through the exceptional point was also observed in that experiment.…”

Section: Introductionmentioning

confidence: 99%