$\mathcal{PT}$-symmetric electronics

Schindler, Joseph; Lin, Zin; Lee, J. M.; Ramezani, Hamidreza; Ellis, F. M.; Kottos, Tsampikos

doi:10.1088/1751-8113/45/44/444029

Cited by 278 publications

(264 citation statements)

References 42 publications

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“…In the broken phase (red curve), the second components of the eigenvectors are purely imaginary, and under conjugation, one of the components transforms into the other. It should be pointed out that the unusual scattering properties of the PT -symmetric medium have also been demonstrated in optics and electronics, both in theories and experiments [41,42,44,45].…”

Section: Scattering Propertiesmentioning

confidence: 94%

PT-Symmetric Acoustics

et al. 2014

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We introduce here the concept of acoustic parity-time (PT ) symmetry and demonstrate the extraordinary scattering characteristics of the acoustic PT medium. On the basis of exact calculations, we show how an acoustic PT -symmetric medium can become unidirectionally transparent at given frequencies. Combining such a PT -symmetric medium with transformation acoustics, we design two-dimensional symmetric acoustic cloaks that are unidirectionally invisible in a prescribed direction. Our results open new possibilities for designing functional acoustic devices with directional responses.

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Section: Scattering Propertiesmentioning

confidence: 94%

PT-Symmetric Acoustics

et al. 2014

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“…Dynamical transitions with the Hamiltonian in Eq. (18) have been studied in, e.g., [45,46] and used in [42,43] to interpret the experimental data. In [45,46] the number of channels is K = 1, and it has been shown that the transition really can be regarded as a second-order phase transition in the sense of thermodynamics in the limit N → ∞.…”

Section: B Dynamical Phase Transitionsmentioning

confidence: 99%

“…EPs of this kind may be studied experimentally, and there is a rapidly increasing number of studies related to fundamental science and technology. For example, there are studies with pump-induced lasers [7,8], microwave cavities and wires [9][10][11][12][13][14][15][16][17], LRC circuits [18], exciton-polariton billiards [19], and more [20,21].…”

Section: Introductionmentioning

confidence: 99%

Spectra, current flow, and wave-function morphology in a modelPT-symmetric quantum dot with external interactions

Tellander

Berggren

2017

Phys. Rev. A

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In this paper we use numerical simulations to study a two-dimensional (2D) quantum dot (cavity) with two leads for passing currents (electrons, photons, etc.) through the system. By introducing an imaginary potential in each lead the system is made symmetric under parity-time inversion (PT symmetric). This system is experimentally realizable in the form of, e.g., quantum dots in low-dimensional semiconductors, optical and electromagnetic cavities, and other classical wave analogs. The computational model introduced here for studying spectra, exceptional points (EPs), wave-function symmetries and morphology, and current flow includes thousands of interacting states. This supplements previous analytic studies of few interacting states by providing more detail and higher resolution. The Hamiltonian describing the system is non-Hermitian; thus, the eigenvalues are, in general, complex. The structure of the wave functions and probability current densities are studied in detail at and in between EPs. The statistics for EPs is evaluated, and reasons for a gradual dynamical crossover are identified.

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“…The stable operating conditions are determined by the amount of gain and loss in the grating, whereby if the magnitudes of the gain and loss are equal, and 2 exceed a certain critical amount, the grating operation becomes unstable (Chong et al 2011;Nixon et al 2012). This critical amount of gain/loss is commonly referred to as the Lasing and Coherent Perfect Absorber (CPAL) point (Chong et al 2011;Phang et al 2013b;Schindler et al 2012), and operation above this point yields an exponential energy growth. In a linear PT grating structure, the CPAL occurs when the trajectories of a pole and a zero of the scattering matrix S coincide on the real frequency axis in the complex frequency plane (Chong et al 2011).…”

Section: Introductionmentioning

confidence: 99%

A versatile all-optical parity-time signal processing device using a Bragg grating induced using positive and negative Kerr-nonlinearity

et al. 2014

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(2015) A versatile all-optical parity-time signal processing device using a Bragg grating induced using positive and negative Kerrnonlinearity. Optical and Quantum Electronics, 47 (1 A note on versions:The version presented here may differ from the published version or from the version of record. If you wish to cite this item you are advised to consult the publisher's version. Please see the repository url above for details on accessing the published version and note that access may require a subscription. Abstract. The properties of gratings with Kerr nonlinearity and PT symmetry are investigated in this paper. The impact of the gain and loss saturation on the response of the grating is analysed for different input intensities and gain/loss parameters. Potential applications of these gratings as switches, logic gates and amplifiers are also shown.

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$\mathcal{PT}$-symmetric electronics

Cited by 278 publications

References 42 publications

PT-Symmetric Acoustics

PT-Symmetric Acoustics

Spectra, current flow, and wave-function morphology in a modelPT-symmetric quantum dot with external interactions

A versatile all-optical parity-time signal processing device using a Bragg grating induced using positive and negative Kerr-nonlinearity

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