Topological Quantum Optics in Two-Dimensional Atomic Arrays

Perczel, Janos; Borregaard, Johannes; Chang, Darrick E.; Pichler, Hannes; Yelin, Susanne F.; Zoller, P.; Lukin, Mikhail D.

doi:10.1103/physrevlett.119.023603

Cited by 189 publications

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“…As was shown in [74] and also observed in [75], all states that lie outside the circle |k| = κ are subradiant, i.e., they decay with a rate much smaller than the single atom decay rate . Hence, remarkably, we find that while in case (i) the dissipation makes the excitation decay after only a few sites, the excitation in case (ii) is much less affected by the dissipation (see discussion in [57]).…”

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confidence: 65%

“…We have shown that one can excite edge states that allow for the transport of an excitation over long distances along the edge of the lattice that are robust to the presence of defects. Moreover, these edge states are remarkably long-lived due to the collective character of the dissipation (this effect has also been investigated in [74,75]). Finally, we have found that, due to the long-ranged character of the interactions, the bulk-boundary relations, well established for topological insulators with short-range interactions, are not generally valid in our setting.…”

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confidence: 95%

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Topological properties of a dense atomic lattice gas

et al. 2017

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Citation for published item:fettlesD oert tF nd win¡ § rD ti § r¡ % nd edmsD ghrles F nd vesnovskyD sgor nd ylmosD fetriz @PHIUA 9opologil properties of dense tomi lttie gsF9D hysil review eFD WT @RAF HRITHQ@AF Further information on publisher's website: eprinted with permission from the emerin hysil oietyX fettlesD oert tFD win¡ § rD ti § r¡ %D edmsD ghrles FD vesnovskyD sgor ylmosD fetriz @PHIUAF opologil properties of dense tomi lttie gsF hysil eview e WT@RAX HRITHQ@A PHIU y the emerin hysil oietyF eders my viewD rowseD ndGor downlod mteril for temporry opying purposes onlyD provided these uses re for nonommeril personl purposesF ixept s provided y lwD this mteril my not e further reproduedD distriutedD trnsmittedD modi(edD dptedD performedD displyedD pulishedD or sold in whole or prtD without prior written permission from the emerin hysil oietyF Additional information: Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-prot purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. We investigate the existence of topological phases in a dense two-dimensional atomic lattice gas. The coupling of the atoms to the radiation field gives rise to dissipation and a nontrivial coherent long-range exchange interaction whose form goes beyond a simple power law. The far-field terms of the potential-which are particularly relevant for atomic separations comparable to the atomic transition wavelength-can give rise to energy spectra with one-sided divergences in the Brillouin zone. The long-ranged character of the interactions has another important consequence: it can break the standard bulk-boundary relation in topological insulators. We show that topological properties such as the transport of an excitation along the edge of the lattice are robust with respect to the presence of lattice defects and dissipation. The latter is of particular relevance as dissipation and coherent interactions are inevitably connected in our setting. DOI: 10.1103/PhysRevA.96.041603 Introduction. Recently, the pursuit of topological phases in quantum many-body systems has been the focus of intense research. The potential application of these topological states for robust quantum computation [1,2] is one of the driving forces for this increased interest. So-called topological insulators are usually characterized by bulk bands separated by a gap and the presence of gapless edge states whose properties are topologically protected against local perturbations such as external disorder or noise [3,4]. Paradigmatic examples of these include the integer and fractional quantum Hall effects, which were initially realized on two...

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Topological properties of a dense atomic lattice gas

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“…Quantum optical properties of lattices of atoms and atomlike emitters are being actively explored both theoretically and experimentally [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15]. In such lattices, atoms are assumed to be confined such that tunneling between sites is negligible and they interact via photon-mediated dipole-dipole interactions giving rise to hybridized atom-photon bands.…”

Section: Introductionmentioning

confidence: 99%

“…The photonic band structure of three-dimensional (3D) atomic lattices has been investigated in a number of studies [2][3][4][5][6]. Recently, there has been significant interest in the photonic properties of two-dimensional (2D) atomic lattices, which have been shown to exhibit a variety of remarkable phenomena, including subradiance [15][16][17][18], near perfect reflection of radiation [12,14], and long-lived topological excitations [10,11].…”

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confidence: 99%

Photonic band structure of two-dimensional atomic lattices

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Two-dimensional atomic arrays exhibit a number of intriguing quantum optical phenomena, including subradiance, nearly perfect reflection of radiation, and long-lived topological edge states. Studies of emission and scattering of photons in such lattices require complete treatment of the radiation pattern from individual atoms, including long-range interactions. We describe a systematic approach to perform the calculations of collective energy shifts and decay rates in the presence of such long-range interactions for arbitrary two-dimensional atomic lattices. As applications of our method, we investigate the topological properties of atomic lattices both in free space and near plasmonic surfaces.

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“…From the experimental side, recent proposals with Shiba states [31][32][33][34], Floquet Hamiltonians [35,36], atoms coupled to radiation fields [37][38][39], and trapped ions [40] opened the possibility to synthesize and observe the mentioned LR physics.…”

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Edge insulating topological phases in a two-dimensional superconductor with long-range pairing

2018

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We study the zero-temperature phase diagram of a two dimensional square lattice loaded by spinless fermions, with nearest-neighbor hopping and algebraically decaying pairing. We find that for sufficiently long-range pairing, new phases occur, not continuously connected with any short-range phase and not belonging to the standard families of topological insulators/superconductors. These phases are signaled by the violation of the area law for the Von Neumann entropy, by semi-integer Chern numbers, and by edge modes with nonzero mass. The latter feature results in the absence of single-fermion edge conductivity, present instead in the short-range limit. The definition of a bulk-topology and the presence of a bulk-boundary correspondence is suggested also for the long-range phases. Recent experimental proposals and advances open the possibility to probe the described long-range effects in near-future realistic set-ups. PACS numbers:Introduction -In recent years, the topological phases of matter have become a central focus for physical investigation. A groundbreaking result is the classification of the symmetry-protected topologically inequivalent classes for non interacting fermionic systems (topological insulators/superconductors) [1][2][3][4][5][6]. This theoretical breakthrough has been probed on particular solid-state compounds [7][8][9][10].Notwithstanding the presence of a nonvanishing bulk energy gap, the most relevant feature displayed by nontrivial topological insulators/superconductors is a conductivity localized on the edges, due to massless edge mode with a dynamics well distinguished from the bulk excitations. Moreover, continuous transitions with a vanishing mass gap generally divide phases with different topology (even if also first order transitions seem possible if perturbative interactions between fermions are added [11]). Regarding the entanglement content, topological insulators/superconductors display exponentially saturating entanglement and correlations, giving rise to the area-law for the Von Neumann entropy between the two elements of a real-space bipartition.These features characterize quantum systems governed by Hamiltonians with short-range (SR) terms. However, in recent years, long-range (LR) classical and quantum systems [12], obtained renewed attention. Independent theoretical works have concluded that LR systems can exhibit many interesting and unusual properties, essentially due to the violation of locality (see e.g. [13][14][15][16][17][18][19][20]). In particular, one-dimensional LR models can host new phases, manifesting striking properties, not present in the SR limit. [15][16][17][21][22][23][24][25][26][27][28][29][30].In spite of these relevant achievements, full comprehension and classification phases emerging from Hamiltonians with LR terms are still not available.In [29] a partial solution to these problems has been discussed, exploiting one-dimensional topological superconductive chains as playgrounds, but inferring nontrivial properties also for LR topological insulators...

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Topological Quantum Optics in Two-Dimensional Atomic Arrays

Cited by 189 publications

References 70 publications

Topological properties of a dense atomic lattice gas

Topological properties of a dense atomic lattice gas

Photonic band structure of two-dimensional atomic lattices

Edge insulating topological phases in a two-dimensional superconductor with long-range pairing

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