Angel Ortega‐Gomez scite author profile

Scaling up quantum technologies entails the challenge of developing large‐scale and high‐performance photonic quantum networks. Engineering novel optical components, with a compact footprint and advanced functionalities, might help addressing this challenge by reducing the size and complexity of optical networks. Here, quantum interference phenomena in Wilkinson power dividers (WPDs), a popular element of microwave networks, is investigated. It is theoretically demonstrated that WPDs grant access to coherent perfect absorption (CPA) quantum state transformations (single photon CPA, coherent absorption of N00N states, two‐photon nonlinear absorption, and absorption of coherence in squeezed light) in CPA networks with a smaller footprint and a reduced number of elements. Additionally, it is shown how a WPD can be designed in a pure silicon‐on‐insulator platform by taking advantage of radiative losses. These findings might represent an important step forward in the development of CPA quantum networks.

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Noise Cancellation Effects in Integrated Photonics with Wilkinson Power Dividers

Ortega‐Gomez¹,

Hernández²,

Oña³

et al. 2023

ACS Photonics

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Wilkinson power dividers (WPDs) are a popular element in RF and microwave technologies known for providing isolation capabilities. However, the benefits that WPDs could offer to integrated photonic systems are far less studied. Here, we investigate the thermal emission from and the noise performance of silicon-on-insulator (SOI) WPDs. We find that WPDs exhibit a noiseless port, with important implications for receiving systems and absorption-based quantum state transformations. At the same time, the thermal signals exiting noisy ports exhibit nontrivial correlations, opening the possibility for noise cancellation. We analyze passive and active networks containing WPDs showing how such nontrivial correlations can prevent the amplification of the thermal noise introduced by WPDs while benefiting from their isolation capabilities. Using this insight, we propose a modified ring-resonator amplifier that improves by N times the SNR in comparison with conventional traveling wave and ring-resonator amplifiers, with N being the number of inputs/outputs of the WPD. We believe that our results represent an important step forward in the implementation of SOI-WPDs and their integration in complex photonic networks, particularly for mid-IR and quantum photonics applications.

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Quantum Interference in Wilkinson Power Dividers (Laser Photonics Rev. 16(8)/2022)

Hernández¹,

Ortega‐Gomez²,

Bravo³

et al. 2022

Laser & Photonics Reviews

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Photonic Quantum Networks Scaling up quantum technologies will require new ideas at the device and systems levels. In article number 2200095, Osmery Hernández and colleagues demonstrate that Wilkinson power dividers (WPDs) reduce the complexity of coherent perfect absorption (CPA) photonic quantum networks, leading to smaller footprints and a reduced number of elements. The image illustrates integrated photonics WPD supporting CPA and perfect transparency of entangled photons.

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