Parity-time-symmetric coupled microring lasers operating around an exceptional point

Hodaei, Hossein; Miri, Mohammad‐Ali; Hassan, Absar U.; Hayenga, William E.; Heinrich, Matthias; Christodoulides, Demetrios N.; Khajavikhan, Mercedeh

doi:10.1364/ol.40.004955

Cited by 112 publications

(50 citation statements)

References 31 publications

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“…Despite having a non‐Hermitian representation, such a system may still support an entirely real spectrum. While originally developed in the context of quantum mechanics , such notions have lately attracted considerable attention in different areas of optics such as photonic lattices, microresonators, gratings, and lasers . In optical settings, a structure is PT symmetric if the real part of the refractive index is an even function of position, whereas the imaginary component (representing gain and loss) exhibits an odd profile.…”

Section: Introductionmentioning

confidence: 99%

“…The PT‐symmetry is achieved using a coupled microring system in which the pump power is selectively withheld from one of the cavities. In such settings, the net differential gain associated with the spectral envelope of the line shape function is systematically enhanced – a direct byproduct of the existence of a non‐Hermitian exceptional point . Exceptional points have been also shown to reverse the dependence of lasing threshold on pump power .…”

Section: Introductionmentioning

confidence: 99%

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Single mode lasing in transversely multi‐moded PT‐symmetric microring resonators

Hodaei

Miri

Hassan

et al. 2016

Laser & Photonics Reviews

109

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Single mode lasing is experimentally demonstrated in a transversely multi-moded InP-based semiconductor microring arrangement. In this system, mode discrimination is attained by judiciously utilizing the exceptional points in a parity-time (PT) symmetric double microring configuration. The proposed scheme is versatile, robust to small fabrication errors, and enables the device to operate in a stable manner considerably above threshold while maintaining spatial and spectral purity. The results presented here pave the way towards a new class of chip-scale semiconductor lasers that utilize gain/loss contrast as a primary mechanism for mode selection.Integrated photonic laser systems with larger cross sections are desirable for many applications since they allow for higher energies within the cavities while managing the thermal load and keeping the impact of optical nonlinearities under control. Unfortunately, however, merely enlarging the transverse dimensions of the waveguides inevitably gives rise to competing higher-order spatial modes. This, in turn, compromises the spectral and spatial fidelity of the laser and limits the power allocated within a specific mode [1]. These limitations exist on all scales, and may even be exacerbated in chip-scale semiconductor lasers, where the large gain bandwidths of the active media already pose a challenge in promoting single-mode operation [2].So far, utilizing intra-cavity dispersive elements has been the primary approach for longitudinal mode selection [3], while tapering along the direction of propagation, engineering the refractive index in the cross section, as well as evanescent filtering are some of the extensively explored techniques to enforce single spatial mode operation in such arrangements [4][5][6][7]. Yet, in spite of their success, they are not always compatible with on-chip microcavity structures and in most cases are quite sensitive to small fabrication tolerances. In this respect, it would be desirable to explore alternative avenues to address these issues.Lately, the selective breaking of parity-time (PT) symmetry has been proposed as a viable strategy for obtaining single transverse mode operation [8]. It is suggested that by pairing an active resonator/waveguide with a lossy but otherwise identical partner, it is possible to enforce single-spatial-mode performance even in the presence of strong mode competition in multi-moded laser/amplifier configurations. In general, a structure is considered to be PT-symmetric if it is invariant under the simultaneous action of the (space) and (time) inversion operations [9]. Despite 2 having a non-Hermitian representation, such a system may still support an entirely real spectrum. While originally developed in the context of quantum mechanics [9,10], such notions have recently attracted considerable attention in different areas of optics such as photonic lattices, microresonators, gratings, and lasers [11][12][13][14][15][16][17][18][19][20][21][22]. In optical settings, a structure is PT symmetric if the real part...

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Single mode lasing in transversely multi‐moded PT‐symmetric microring resonators

Hodaei

Miri

Hassan

et al. 2016

Laser & Photonics Reviews

109

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“…The first approach is to use optical feedback in a cavity to achieve single-mode operation456; the second is to enhance mode confinement by reducing the mode size in a laser cavity to achieve single-mode operation789; the third is to shape the spatial profile of a pump light to a laser cavity to achieve mode selection10; and the fourth approach is to use parity-time (PT) symmetry111213141516 to implement mode selection. The last approach has been an active topic and has been heavily researched recently1718192021.…”

mentioning

confidence: 99%

“…In the fourth approach, mode selection is achieved based on PT symmetry by manipulating the interplay between gain and loss in a laser cavity1718192021. In a coupled arrangement with two identical microring resonators one is experiencing gain, whereas the other is experiencing an equal-magnitude loss, to form a PT-symmetry situation.…”

mentioning

confidence: 99%

“…Therefore, the desired mode can be controlled for single-mode operation in an inherently multi-mode microring laser18. The breaking of the PT-symmetry condition provides a simple and effective solution to achieve single-mode lasing by allowing the desired mode to have a higher gain, while suppressing other modes1718192021. In refs 18, 19, a single-mode lasing was demonstrated with an enhanced mode discrimination by using the exceptional points in a PT-symmetric coupled ring resonator structure20.…”

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confidence: 99%

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An integrated parity-time symmetric wavelength-tunable single-mode microring laser

et al. 2017

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Mode control in a laser cavity is critical for a stable single-mode operation of a ring laser. In this study we propose and experimentally demonstrate an electrically pumped parity-time (PT)-symmetric microring laser with precise mode control, to achieve wavelength-tunable single-mode lasing with an improved mode suppression ratio. The proposed PT-symmetric laser is implemented based on a photonic integrated circuit consisting of two mutually coupled active microring resonators. By incorporating multiple semiconductor optical amplifiers in the microring resonators, the PT-symmetry condition can be achieved by a precise manipulation of the interplay between the gain and loss in the two microring resonators, and the incorporation of phase modulators in the microring resonators enables continuous wavelength tuning. Single-mode lasing at 1,554.148 nm with a sidemode suppression ratio exceeding 36 dB is demonstrated and the lasing wavelength is continuously tunable from 1,553.800 to 1,554.020 nm.

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Recent Progress in Nanolaser Technology

et al. 2020

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Nanolasers are key elements in the implementation of optical integrated circuits owing to their low lasing thresholds, high energy efficiencies, and high modulation speeds. With the development of semiconductor wafer growth and nanofabrication techniques, various types of wavelength-scale and subwavelength-scale nanolasers have been proposed. For example, photonic crystal lasers and plasmonic lasers based on the feedback mechanisms of the photonic bandgap and surface plasmon polaritons, respectively, have been successfully demonstrated. More recently, nanolasers employing new mechanisms of light confinement, including parity-time symmetry lasers, photonic topological insulator lasers, and bound states in the continuum lasers, have been developed. Here, the operational mechanisms, optical characterizations, and practical applications of these nanolasers based on recent research results are outlined. Their scientific and engineering challenges are also discussed.

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Parity-time-symmetric coupled microring lasers operating around an exceptional point

Cited by 112 publications

References 31 publications

Single mode lasing in transversely multi‐moded PT‐symmetric microring resonators

Single mode lasing in transversely multi‐moded PT‐symmetric microring resonators

An integrated parity-time symmetric wavelength-tunable single-mode microring laser

Recent Progress in Nanolaser Technology

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