Topological insulator laser: Theory

Harari, Gal; Bandres, Miguel A.; Lumer, Yaakov; Rechtsman, Mikael C.; Chong, Yidong; Khajavikhan, Mercedeh; Christodoulides, Demetrios N.; Segev, Mordechai

doi:10.1126/science.aar4003

Cited by 848 publications

(633 citation statements)

References 48 publications

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“…The interest in non-Hermitian Hamiltonians was originally focused in  -symmetric Hamiltonians [23] as a generalization of quantum mechanics where the Hermiticity constraint could be removed while keeping a real spectra. Today, this has shifted to non-Hermitian Hamiltonians regarded as an effective description of, for example, open quantum systems [24,25], where the finite lifetime introduced by electronelectron or electron-phonon interactions [26][27][28], or disorder [29], is modeled through a non-Hermitian term, or in the physics of lasing [30][31][32][33][34]. An additional source of momentum in this field comes from the study of systems where the quantum mechanical description is used after mapping to a Schrödinger-like equation, as in systems with gain and loss (as found in optics and photonics [35][36][37][38]), surface Maxwell waves [39], and topoelectrical circuits [40,41].…”

Section: Introductionmentioning

confidence: 99%

Perspective on topological states of non-Hermitian lattices

Torres

2019

J. Phys. Mater.

143

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The search of topological states in non-Hermitian systems has gained a strong momentum over the last two years climbing to the level of an emergent research front. In this perspective we give an overview with a focus on connecting this topic to others like Floquet systems. Furthermore, using a simple scattering picture we discuss an interpretation of concepts like the Hamiltonian's defectiveness, i.e. the lack of a full basis of eigenstates, crucial in many discussions of topological phases of non-Hermitian Hamiltonians.

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Section: Introductionmentioning

confidence: 99%

Perspective on topological states of non-Hermitian lattices

Torres

2019

J. Phys. Mater.

143

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“…Such chiral edge mode is robust in a sense that backscattering is prohibited in the presence of local disorder due to timereversal symmetry breaking of the system. The unprecedented properties of the topological edge mode bring the interest of making it as a light source, especially a laser [28,29,71]. In general, defects and disorders in the laser cavity lead to scattering loss, which degrades the performance of laser by reducing the quality factor and lowering the output efficiency.…”

Section: D Topological Laser With Trs Breakingmentioning

confidence: 99%

“…There is another class of two-dimensional topological lasers, which do not break the time reversal symmetry [29,71]. The structure is based on the construction of the Harper-Hofstadter model using ring resonators originally realized by [5,6] where we have set the lattice spacing to be unity and assumed that the hopping strength is isotropic.…”

Section: D Topological Lasers Without Breaking Trsmentioning

confidence: 99%

Active topological photonics

et al. 2020

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Topological photonics has emerged as a novel route to engineer the flow of light. Topologically-protected photonic edge modes, which are supported at the perimeters of topologically-nontrivial insulating bulk structures, have been of particular interest as they may enable low-loss optical waveguides immune to structural disorder. Very recently, there is a sharp rise of interest in introducing gain materials into such topological photonic structures, primarily aiming at revolutionizing semiconductor lasers with the aid of physical mechanisms existing in topological physics. Examples of remarkable realizations are topological lasers with unidirectional light output under time-reversal symmetry breaking and topologically-protected polariton and micro/nano-cavity lasers. Moreover, the introduction of gain and loss provides a fascinating playground to explore novel topological phases, which are in close relevance to non-Hermitian and paritytime symmetric quantum physics and are in general difficult to access using fermionic condensed matter systems. Here, we review the cutting-edge research on active topological photonics, in which optical gain plays a pivotal role. We discuss recent realizations of topological lasers of various kinds, together with the underlying physics explaining the emergence of topological edge modes. In such demonstrations, the optical modes of the topological lasers are determined by the dielectric structures and support lasing oscillation with the help of optical gain. We also address recent researches on topological photonic systems in which gain and loss themselves essentially influence on topological properties of the bulk systems. We believe that active topological photonics provides powerful means to advance micro/nanophotonics systems for diverse applications and topological physics itself as well.

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“…Despite early studies in nonreciprocal systems, photonic topological edge states without breaking time‐reversal symmetry (TRS) can be realized in systems that allow an analog of quantum spin‐Hall effect with a pseudospin degree of freedom of photons. Various optical degrees of freedom have been used as pseudospin, such as polarizations in bianisotropic metamaterials, TE and TM modes in photonic crystals, chiralities of whispering‐gallery modes in ring resonators, and more recently p ‐ and d ‐orbitals in artificial photonic atoms . However, these schemes are either incompatible with integrated photonic platforms or suffer from bulky footprints and large out‐of‐plane radiation loss …”

Section: Introductionmentioning

confidence: 99%

Topological Photonic Integrated Circuits Based on Valley Kink States

Sun

2019

Laser & Photonics Reviews

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Valley pseudospin, a new degree of freedom in photonic lattices, provides an intriguing way to manipulate photons and enhance the robustness of optical networks. Here, topological waveguiding, refracting, resonating, and routing of valley‐polarized photons in integrated circuits are experimentally demonstrated. Specifically, it is shown that at the domain wall between photonic crystals of different topological valley phases, there exists a topologically protected valley kink state that is backscattering‐free at sharp bends and terminals. These valley kink states are further harnessed for constructing high‐Q topological photonic crystal cavities with tortuously shaped cavity geometries. A novel optical routing scheme at an intersection of multiple valley kink states is also demonstrated, where light splits counterintuitively due to the valley pseudospin of photons. These results can not only lead to robust optical communication and signal processing, but also open the door for fundamental research of topological photonics in areas such as lasing, quantum photon‐pair generation, and optomechanics.

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Topological insulator laser: Theory

Cited by 848 publications

References 48 publications

Perspective on topological states of non-Hermitian lattices

Perspective on topological states of non-Hermitian lattices

Active topological photonics

Topological Photonic Integrated Circuits Based on Valley Kink States

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