Pulse propagation in a decoupled two-core fiber

Liu, M.; Chiang, Kin Seng

doi:10.1364/oe.18.021261

Cited by 11 publications

(6 citation statements)

References 21 publications

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“…Recently, a photonic bandgap two-core fiber that gives C ¼ 0 has been demonstrated [35]. Nevertheless, such a decoupled twocore fiber can have an appreciable value of C 1 (around −1 ps=m), while maintaining C ¼ 0 [36].…”

Section: Coupled-mode Equationsmentioning

confidence: 99%

Modulation instabilities in two-core optical fibers

Chiang

Chow

2011

J. Opt. Soc. Am. B

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Modulation instability (MI) of cw states of a two-core fiber, incorporating the effects of coupling-coefficient dispersion (CCD), is studied by solving a pair of generalized, linearly coupled nonlinear Schrödinger equations. CCD refers to the property that the coupling coefficient depends on the optical wavelength, and earlier studies of MI do not account for this physics. CCD does not seriously affect the symmetric/antisymmetric cw, but can drastically modify the MI of the asymmetric state. Generally, new MI frequency bands are produced, and CCD reduces (enhances) the original MI band in the anomalous (normal) dispersion regime. Another remarkable result is the existence of a critical value for the CCD, where the MI gain spectrum undergoes an abrupt change. In the anomalous dispersion regime, a new low-frequency MI band is generated. In the normal dispersion regime, an MI band vanishes, reappears, and then moves up in frequency on crossing this critical value. In both dispersion regimes, the relative magnitude of the low-frequency band and the high-frequency band depends strongly on the total input power. It is possible to switch the dominant MI frequency between a low frequency and a high frequency by tuning the total input power, providing a promising scheme to manipulate MI-related nonlinear effects in two-core fibers. The MI bands are independent of the third-order dispersion, but can be shifted significantly by self-steepening at a sufficiently high total input power. The evolution of MI from a cw input is also demonstrated with a wave propagation study.

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Section: Coupled-mode Equationsmentioning

confidence: 99%

Modulation instabilities in two-core optical fibers

Chiang

Chow

2011

J. Opt. Soc. Am. B

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“…Although in the picosecond regime MCF propagation models have been proposed in [56,57] including polarization effects and the random longitudinal fiber perturbations (but omitting the temporal fluctuations), in the femtosecond regime, existing MCF propagation models exclude polarization effects and omit both temporal and longitudinal random perturbations of the fiber [58][59][60]. In order to include these realistic fiber conditions in the mathematical description of the propagation of femtosecond optical pulses through a MCF, a theoretical model is proposed in [61] based on the concept of local modes.…”

Section: Intermodal Dispersion and Higher-order Coupling And Nonlineamentioning

confidence: 99%

“…In fact, MCFs can be employed to elucidate the underlying wave propagation phenomena of any physical system with propagating equations of the form of the CNLSEs, for example, superposed nonlinear waves in coherently coupled Bose-Einstein condensates [130] or turbocharge applications in acoustics [131]. Remarkably, in acoustics, the CLMT reported in [60] can play an essential role. Time-varying multi-core cylindrical acoustic ducts can be engineered with the same modal properties as optical MCFs.…”

Section: Multi-core Fiber Opportunities In Experimental Physicsmentioning

confidence: 99%

Multi-Core Optical Fibers: Theory, Applications and Opportunities

Macho¹,

Llorente²

2018

Selected Topics on Optical Fiber Technologies and Applications

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Multi-core fibers (MCFs) have sparked a new paradigm in optical communications, as they can significantly increase the Shannon capacity of optical networks based on singlecore fibers. In addition, MCFs constitute a useful platform for testing different physical phenomena, such as quantum or relativistic effects, as well as to develop interesting applications in various fields, such as biological and medical imaging. Motivated by the potential applications of these new fibers, we will perform a detailed review of the MCF technology including a theoretical analysis of the main physical impairments and new dispersive effects of these fibers, and we will discuss their emerging applications and opportunities in different branches of science.

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“…Recently, a photonic bandgap DWG that gives zero coupling has been demonstrated [26]. However, such a decoupled DWG will have an appreciable value of CCD, while maintaining the zero coupling term [27]. In Eq.…”

Section: Analysis With Nonzero Ccd and Zero Coupling Termmentioning

confidence: 99%