Parity–time synthetic photonic lattices

Regensburger, Alois; Bersch, Christoph; Miri, Mohammad‐Ali; Onishchukov, G.; Christodoulides, Demetrios N.; Peschel, Ulf

doi:10.1038/nature11298

Cited by 1,847 publications

(1,505 citation statements)

References 48 publications

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“…We expect that our predictions can be verified by combining recent advances in shaping complex wave fronts 3 with new techniques to fabricate non-Hermitian scattering structures with gain and loss [7][8][9][10] . As the precise combination of gain and loss in the same device is challenging, we suggest using passive structures with only loss in the first place.…”

Section: Discussionmentioning

confidence: 66%

“…They also remain valid for any sign of Kerr nonlinearity and thus allow us to perform a modulational stability analysis for non-homogeneous potentials. The most appropriate context to study the MI of such solutions is that of PT -symmetric optics [6][7][8][9][10][11]14,[19][20][21][22]24 . We find that in the selffocusing regime, the waves are always unstable, whereas in the defocusing regime the instability appears for specific values of Bloch momenta.…”

Section: Discussionmentioning

confidence: 99%

“…Such non-Hermitian potential regions 4,5 , which serve as sources and sinks for waves, respectively, can give rise to novel wave effects that are impossible to realize with conventional, Hermitian potentials. Examples of this kind, which were meanwhile also realized in the experiment [6][7][8][9][10] , are the unidirectional invisibility of a gain-loss potential 11 , devices that can simultaneously act as laser and as a perfect absorber [12][13][14] and resonant structures with unusual features like non-reciprocal light transmission 10 or loss-induced lasing [15][16][17] . In particular, systems with a so-called parity-time (PT ) symmetry 18 , where gain and loss are carefully balanced, have recently attracted enormous interest in the context of nonHermitian photonics [19][20][21][22][23][24] .…”

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confidence: 99%

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Constant-intensity waves and their modulation instability in non-Hermitian potentials

et al. 2015

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In all of the diverse areas of science where waves play an important role, one of the most fundamental solutions of the corresponding wave equation is a stationary wave with constant intensity. The most familiar example is that of a plane wave propagating in free space. In the presence of any Hermitian potential, a wave's constant intensity is, however, immediately destroyed due to scattering. Here we show that this fundamental restriction is conveniently lifted when working with non-Hermitian potentials. In particular, we present a whole class of waves that have constant intensity in the presence of linear as well as of nonlinear inhomogeneous media with gain and loss. These solutions allow us to study the fundamental phenomenon of modulation instability in an inhomogeneous environment. Our results pose a new challenge for the experiments on non-Hermitian scattering that have recently been put forward.

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Section: Discussionmentioning

confidence: 66%

Section: Discussionmentioning

confidence: 99%

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confidence: 99%

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Constant-intensity waves and their modulation instability in non-Hermitian potentials

et al. 2015

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“…For example, waveguide arrays are widely used in emerging applications such as optical-phased arrays [18][19][20][21] , space-division multiplexing 22 and chip-scale optical interconnects 23,24 , and conventional applications such as wavelength-division multiplexers 25,26 . On the other hand, a waveguide array or a waveguide lattice can also be viewed 27 as fully analogous to a periodic chain of atoms, which lends itself to a broad spectrum of fascinating scientific possibilities ranging from Anderson localization of light 28,29 to parity-time symmetric effects 30 . Thus far, in most studies, the pitch associated with such relatively simple waveguide arrays/lattices has been typically large, ranging from a few micrometres to tens of micrometres (or a multiple of wavelengths) 18,19,21,31,32 .…”

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confidence: 99%

High-density waveguide superlattices with low crosstalk

et al. 2015

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Silicon photonics holds great promise for low-cost large-scale photonic integration. In its future development, integration density will play an ever-increasing role in a way similar to that witnessed in integrated circuits. Waveguides are perhaps the most ubiquitous component in silicon photonics. As such, the density of waveguide elements is expected to have a crucial influence on the integration density of a silicon photonic chip. A solution to highdensity waveguide integration with minimal impact on other performance metrics such as crosstalk remains a vital issue in many applications. Here, we propose a waveguide superlattice and demonstrate advanced superlattice design concepts such as interlacing-recombination that enable high-density waveguide integration at a half-wavelength pitch with low crosstalk. Such waveguide superlattices can potentially lead to significant reduction in on-chip estate for waveguide elements and salient enhancement of performance for important applications, opening up possibilities for half-wavelength-pitch optical-phased arrays and ultra-dense space-division multiplexing.

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“…Recent experimental realization of PT symmetric optical systems with balanced gain and loss has attracted a lot of attention [1][2][3]. The PT symmetric optical systems lead to interesting results such as unconventional beam refraction and power oscillation [4][5][6], nonreciprocal Bloch oscillations [7], unidirectional invisibility [8], an additional type of Fano resonance [9], and chaos [10].…”

Section: Introductionmentioning

confidence: 99%

PT symmetric Aubry–Andre model

Yüce¹

2014

Physics Letters A

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PT Symmetric Aubry-Andre Model describes an array of N coupled optical waveguides with position dependent gain and loss. We show that the reality of the spectrum depends sensitively on the degree of disorder for small number of lattice sites. We obtain the Hofstadter Butterfly spectrum and discuss the existence of the phase transition from extended to localized states. We show that rapidly changing periodical gain/loss materials almost conserves the total intensity.

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Parity–time synthetic photonic lattices

Cited by 1,847 publications

References 48 publications

Constant-intensity waves and their modulation instability in non-Hermitian potentials

Constant-intensity waves and their modulation instability in non-Hermitian potentials

High-density waveguide superlattices with low crosstalk

PT symmetric Aubry–Andre model

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