Advancements in quantum information: dissipative stabilisation and microwave quantum illumination

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Angeletti, Jacopo (2024) Advancements in quantum information: dissipative stabilisation and microwave quantum illumination. [Tesi di dottorato]

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Tipologia del documento:	Tesi di dottorato
Lingua:	English
Titolo:	Advancements in quantum information: dissipative stabilisation and microwave quantum illumination
Autori:	Autore Email Angeletti, Jacopo jacopo.angeletti@unina.it
Data:	11 Marzo 2024
Numero di pagine:	73
Istituzione:	Università degli Studi di Napoli Federico II
Dipartimento:	Fisica
Dottorato:	Quantum Technologies (Tecnologie Quantistiche)
Ciclo di dottorato:	36
Coordinatore del Corso di dottorato:	nome email Tafuri, Francesco francesco.tafuri@unina.it
Tutor:	nome email David, Vitali [non definito]
Data:	11 Marzo 2024
Numero di pagine:	73
Parole chiave:	Quantum information, dissipative dynamics, quantum illumination
Settori scientifico-disciplinari del MIUR:	Area 02 - Scienze fisiche > FIS/02 - Fisica teorica, modelli e metodi matematici
Depositato il:	14 Mar 2024 18:57
Ultima modifica:	10 Mar 2026 08:09
URI:	http://www.fedoa.unina.it/id/eprint/15412

Abstract

Positioned at the forefront of scientific progress, the quantum realm promises transformative advancements, reshaping our responses to intricate challenges. In the dynamic landscape of quantum technologies, this doctoral thesis endeavors to unravel two distinct facets. The first part delves into the complexities of steering a quantum array into a pure steady state, where distant, non-directly interacting qubits become entangled. By artfully manipulating dissipative dynamics on a central element, we not only showcase the attainability of an entangled steady state, but also underscore its resilience to additional decoherence. With broad applications across atomic systems and solid-state nano-devices, this approach allows for the realization of diverse geometries. Shifting focus to the second part, our attention turns to the quantum illumination, addressing imperfections inherent in experimental setups. Here, correlation-to-displacement conversion-based receivers take the spotlight, revealing their efficacy in amplifying return signals to counter losses in heterodyne detection. Notably, a simple Kennedy receiver outperforms classical counterparts in practical settings, presenting a quantum advantage over known quantum receivers. The synthesis of theoretical exploration and practical enhancements contributes meaningfully to the evolving narrative of quantum technologies, marking a distinctive stride towards realizing their potential.

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