Quantum dynamics of propagating photons with strong interactions: a generalized input–output formalism

Caneva, Tommaso; Manzoni, Marco T.; Shi, Ting-Yun; Douglas, James S.; Cirac, J. I.; Chang, Darrick E.

doi:10.1088/1367-2630/17/11/113001

Cited by 164 publications

(209 citation statements)

References 49 publications

(114 reference statements)

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“…The simplest example of a situation that cannot readily be achieved using (short-range) Rydberg interactions is a spatially uniform interaction across the atomic ensemble fðz j ; z l Þ ¼ U (Caneva et al, 2015;Douglas, Caneva, and Chang, 2016). In this case the transmission of single photons is unaffected by the interaction, where an individual photon entering the medium sees the normal EIT response of an atom shown in Fig.…”

Section: Quantum Dielectrics: Photon-photon Interactionsmentioning

confidence: 99%

Colloquium : Quantum matter built from nanoscopic lattices of atoms and photons

et al. 2018

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This Colloquium describes a new paradigm for creating strong quantum interactions of light and matter by way of single atoms and photons in nanoscopic lattices. Beyond the possibilities for quantitative improvements for familiar phenomena in atomic physics and quantum optics, there is a growing research community that is exploring novel quantum phases and phenomena that arise from atom-photon interactions in one-and two-dimensional nanophotonic lattices. Nanophotonic structures offer the intriguing possibility to control atom-photon interactions by engineering the medium properties through which they interact. An important aspect of these new research lines is that they have become possible only by pushing the state-of-the-art capabilities in nanophotonic device fabrication and by the integration of these capabilities into the realm of ultracold atoms. This Colloquium attempts to inform a broad physics community of the emerging opportunities in this new field on both theoretical and experimental fronts. The research is inherently multidisciplinary, spanning the fields of nanophotonics, atomic physics, quantum optics, and condensed matter physics.

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Section: Quantum Dielectrics: Photon-photon Interactionsmentioning

confidence: 99%

Colloquium : Quantum matter built from nanoscopic lattices of atoms and photons

et al. 2018

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“…To this end, we derive and apply a two-photon bi-directional Fock state master equation. This approach differs from the most common techniques that are used to study the quantum dynamics of waveguide QED systems, namely Lehmberg type master equations [21,28], the real space formalism [29] and generalized input-out theory [30].…”

Section: Introductionmentioning

confidence: 99%

Two-photon entanglement in multiqubit bidirectional-waveguide QED

Mirza

Schotland

2016

Phys. Rev. A

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We study entanglement generation and control in bi-directional waveguide QED driven by a twophoton Gaussian wavepacket. In particular, we focus on how increasing the number of qubits affects the overall average pairwise entanglement in the system. We also investigate how the presence of a second photon can introduce non-linearities, thereby manipulating the generated entanglement. In addition, we show that through the introduction of chirality and small decay rates, entanglement can be stored and enhanced up to factors of 2 and 3, respectively. Finally, we analyze the influence of finite detunnings and time-delays on the generated entanglement.

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“…The three main approaches used in waveguide QED to study scattering of photons and entanglement are: the real space formalism [18], the input-output formalism [19,20] and other master equation approaches [14,21]. The main novelty of using the Fock state master equation relies on the fact that it captures both the qubit dynamics and keeps track of the state of the reservoirs at the same time, due to its non-markovian structure.…”

Section: Introductionmentioning

confidence: 99%

Multiqubit entanglement in bidirectional-chiral-waveguide QED

2016

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We study the generation of entanglement induced by a single-photon Gaussian wavepacket in multi-atom bi-directional waveguide QED. In particular, we investigate the effect of increasing the number of atoms on the average pairwise entanglement. We demonstrate by selecting smaller decay rates and in chiral waveguide settings, that both entanglement survival times and maximum generated entanglement can be increased by at least a factor of ∼ 3/2, independent of the number of atoms. In addition, we analyze the influence of detuning and delays on the robustness of the generated entanglement. There are potential applications of our results in entanglement based multi-qubit quantum networks.

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Quantum dynamics of propagating photons with strong interactions: a generalized input–output formalism

Cited by 164 publications

References 49 publications

Colloquium : Quantum matter built from nanoscopic lattices of atoms and photons

Colloquium : Quantum matter built from nanoscopic lattices of atoms and photons

Two-photon entanglement in multiqubit bidirectional-waveguide QED

Multiqubit entanglement in bidirectional-chiral-waveguide QED

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