Muriel Béchu scite author profile

Plasmonics is a rapidly emerging platform for quantum state engineering with the potential for building ultra-compact and hybrid optoelectronic devices. Recent experiments have shown that despite the presence of decoherence and loss, photon statistics and entanglement can be preserved in single plasmonic systems. This preserving ability should carry over to plasmonic metamaterials, whose properties are the result of many individual plasmonic systems acting collectively, and can be used to engineer optical states of light. Here, we report an experimental demonstration of quantum state filtering, also known as entanglement distillation, using a metamaterial. We show that the metamaterial can be used to distill highly entangled states from less entangled states. As the metamaterial can be integrated with other optical components this work opens up the intriguing possibility of incorporating plasmonic metamaterials in on-chip quantum state engineering tasks.

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Active control of a plasmonic metamaterial for quantum state engineering

Uriri

Tashima

Zhang

et al. 2018

Phys. Rev. A

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We experimentally demonstrate the active control of a plasmonic metamaterial operating in the quantum regime. A two-dimensional metamaterial consisting of unit cells made from gold nanorods is investigated. Using an external laser we control the temperature of the metamaterial and carry out quantum process tomography on single-photon polarization-encoded qubits sent through, characterizing the metamaterial as a variable quantum channel. The overall polarization response can be tuned by up to 33% for particular nanorod dimensions. To explain the results, we develop a theoretical model and find that the experimental results match the predicted behavior well. This work goes beyond the use of simple passive quantum plasmonic systems and shows that external control of plasmonic elements enables a flexible device that can be used for quantum state engineering.

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Spectroscopic studies of resonant coupling of silver optical antenna arrays to a near-surface quantum well

Gehl

Zandbergen

Gibson

et al. 2014

J. Opt.

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The coupling of radiation emitted on semiconductor inter-band transitions to resonant optical-antenna arrays allows for enhanced light–matter interaction via the Purcell effect. Semiconductor optical gain also potentially allows for loss reduction in metamaterials. Here we extend our previous work on optically pumped individual near-surface InGaAs quantum wells coupled to silver split-ring-resonator arrays to wire and square-antenna arrays. By comparing the transient pump-probe experimental results with the predictions of a simple model, we find that the effective coupling is strongest for the split rings, even though the split rings have the weakest dipole moment. The effect of the latter must thus be overcompensated by a smaller effective mode volume of the split rings. Furthermore, we also present a systematic variation of the pump-pulse energy, which was fixed in our previous experiments.

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Quantum Entanglement Distillation Using an Optical Metamaterial

Béchu

Asano

Tame

et al. 2015

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Nonlinear Behavior of Metallic Antennae Resonantly Coupled to a Quantum Well

Gehl

Zandbergen

Béchu

et al. 2013

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Muriel Béchu

Distillation of photon entanglement using a plasmonic metamaterial

Active control of a plasmonic metamaterial for quantum state engineering

Spectroscopic studies of resonant coupling of silver optical antenna arrays to a near-surface quantum well

Quantum Entanglement Distillation Using an Optical Metamaterial

Nonlinear Behavior of Metallic Antennae Resonantly Coupled to a Quantum Well

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