Artificial non-Gaussian operations and states for quantum information processing applications

PROVAZNÍK, Jan

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Theses h36jci

Artificial non-Gaussian operations and states for quantum information processing applications – Mgr. Jan PROVAZNÍK

Mgr. Jan PROVAZNÍK

Doctoral thesis

Artificial non-Gaussian operations and states for quantum information processing applications

Artificial nonlinearity for quantum information processing applications

Abstract:

Quantum non-Gaussian operations are one of the essential ingredients needed for universal quantum computation with continuous-variable quantum states of light. The scarcity of naturally occurring non-Gaussian interactions can be compensated with suitable measurement-induced non-Gaussian operations. Their implementations still require high-quality quantum non-Gaussian states that can be manufactured artificially with various techniques of quantum state synthesis. Several original research papers are covered in this dissertation, starting with a proposal for improved single photon subtraction procedure which can be utilized within specific protocols for state synthesis and in entanglement distillation. Another avenue of research focuses on preparation of ancillary non-Gaussian states needed in measurement-induced cubic phase interaction and studies the effects of different photonic detectors on the quality of prepared physical approximations of cubic phase states. The analysis is complemented by a novel approach towards dealing with numerical issues inherent to numerical simulations of continuous-variable quantum systems. Quantum non-Gaussian states, despite their critical role in quantum computation and communication, are susceptible to loss. A particular decoherence mitigation strategy based on Gaussian operations is presented and investigated in the dissertation. Its effects against decoherence due to loss combined with thermal noise are discussed and analyzed for the family of quantum-optical Schrodinger states of light. % Quantum non-Gaussian Schrodinger states serve an important role in quantum computation and communication, however, their non-Gaussian features are susceptible to loss. In a further direction of research a particular mitigation strategy aiming to reduce their decoherence due to loss combined with thermal noise is discussed and analyzed. Ongoing research directions presented in the dissertation include an analysis of realistic experimental conditions required for synthesis of certifiable quantum states of four photons, and a novel algorithm with exponential improvement in computational complexity is introduced for calculation of a special qualitative measure of non-Gaussian resources, enabling its application in complex scenarios. The dissertation concludes with a brief incursion into the realm of genuine multi-partite entangled states. Certain classes of these states can be detected using optimal witnesses obtained with the aid of semi-definite programming. The pertinent semi-definite programs were implemented in collaboration with experimental group aiming to prepare and certify a special discrete-variable state of light with genuine multi-partite entanglement provable solely from its separable two-body marginals. In further theoretical collaboration similarly exotic states were discovered in the domain of continuous-variable light. These efforts eventually culminated in development of open-source software libraries presented within the dissertation. …more

Abstract:

Quantum non-Gaussian operations are one of the essential ingredients needed for universal quantum computation with continuous-variable quantum states of light. The scarcity of naturally occurring non-Gaussian interactions can be compensated with suitable measurement-induced non-Gaussian operations. Their implementations still require high-quality quantum non-Gaussian states that can be manufactured artificially with various techniques of quantum state synthesis. Several original research papers are covered in this dissertation, starting with a proposal for improved single photon subtraction procedure which can be utilized within specific protocols for state synthesis and in entanglement distillation. Another avenue of research focuses on preparation of ancillary non-Gaussian states needed in measurement-induced cubic phase interaction and studies the effects of different photonic detectors on the quality of prepared physical approximations of cubic phase states. The analysis is complemented by a novel approach towards dealing with numerical issues inherent to numerical simulations of continuous-variable quantum systems. Quantum non-Gaussian states, despite their critical role in quantum computation and communication, are susceptible to loss. A particular decoherence mitigation strategy based on Gaussian operations is presented and investigated in the dissertation. Its effects against decoherence due to loss combined with thermal noise are discussed and analyzed for the family of quantum-optical Schrodinger states of light. % Quantum non-Gaussian Schrodinger states serve an important role in quantum computation and communication, however, their non-Gaussian features are susceptible to loss. In a further direction of research a particular mitigation strategy aiming to reduce their decoherence due to loss combined with thermal noise is discussed and analyzed. Ongoing research directions presented in the dissertation include an analysis of realistic experimental conditions required for synthesis of certifiable quantum states of four photons, and a novel algorithm with exponential improvement in computational complexity is introduced for calculation of a special qualitative measure of non-Gaussian resources, enabling its application in complex scenarios. The dissertation concludes with a brief incursion into the realm of genuine multi-partite entangled states. Certain classes of these states can be detected using optimal witnesses obtained with the aid of semi-definite programming. The pertinent semi-definite programs were implemented in collaboration with experimental group aiming to prepare and certify a special discrete-variable state of light with genuine multi-partite entanglement provable solely from its separable two-body marginals. In further theoretical collaboration similarly exotic states were discovered in the domain of continuous-variable light. These efforts eventually culminated in development of open-source software libraries presented within the dissertation. …more

Keywords

quantum optics quantum states of light quantum information processing quantum non-Gaussianity continuous-variables numerical simulation numerical optimization cubic phase states decoherence mitigation coherent Schrodinger states Fock state capability genuine multi-partite entanglement

Language used: English

Date on which the thesis was submitted / produced: 30. 8. 2024

Thesis defence

Supervisor: doc. Mgr. Petr Marek, Ph.D., doc. Mgr. Petr Marek, Ph.D.

Citation record

Cite this text

ISO 690-compliant citation record:

PROVAZNÍK, Jan. \textit{Artificial non-Gaussian operations and states for quantum information processing applications}. Online. Doctoral theses, Dissertations. Olomouc: Palacký University Olomouc, Faculty of Science. 2024. Available from: https://theses.cz/id/h36jci/.

@PhdThesis{PROVAZNIK2024thesis,
AUTHOR = "PROVAZNÍK, Jan",
TITLE = "Artificial non-Gaussian operations and states for quantum information processing applications [online]",
YEAR = "2024 [cit. 2024-11-12]",
TYPE = "Doctoral theses, Dissertations",
SCHOOL = "Palacký University Olomouc, Faculty of ScienceOlomouc",
NOTE = "SUPERVISOR: doc. Mgr. Petr Marek, Ph.D., doc. Mgr. Petr Marek, Ph.D.",
URL = "https://theses.cz/id/h36jci/",
}

@PhdThesis{PROVAZNIK2024thesis,
AUTHOR = {PROVAZNÍK, Jan},
TITLE = {Artificial non-Gaussian operations and states for quantum information processing applications},
YEAR = {2024},
TYPE = {Doctoral theses, Dissertations},
INSTITUTION = {Palacký University Olomouc, Faculty of Science},
LOCATION = {Olomouc},
SUPERVISOR = {doc. Mgr. Petr Marek, Ph.D., doc. Mgr. Petr Marek, Ph.D.},
URL = {https://theses.cz/id/h36jci/},
URL_DATE = {2024-11-12},
}

{{Citace kvalifikační práce
 | příjmení = PROVAZNÍK
 | jméno = Jan
 | instituce = Palacký University Olomouc, Faculty of Science
 | titul = Artificial non-Gaussian operations and states for quantum information processing applications
 | url = https://theses.cz/id/h36jci/
 | typ práce = Doctoral theses, Dissertations
 | vedoucí = doc. Mgr. Petr Marek, Ph.D., doc. Mgr. Petr Marek, Ph.D.
 | rok = 2024
 | počet stran =
 | strany =
 | citace = 2024-11-12
 | poznámka =
 | jazyk = 
}}

The right form of listing the thesis as a source quoted

PROVAZNÍK, Jan. Artificial non-Gaussian operations and states for quantum information processing applications. Olomouc, 2024. disertační práce (Ph.D.). UNIVERZITA PALACKÉHO V OLOMOUCI. Přírodovědecká fakulta

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Institution archiving the thesis and making it accessible: UNIVERZITA PALACKÉHO V OLOMOUCI, Přírodovědecká fakulta

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Palacký University Olomouc

Faculty of Science

Doctoral programme / field:
Physics / Optics and Optoelectronics

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Artificial non-Gaussian operations and states for quantum information processing applications – Mgr. Jan PROVAZNÍK

Mgr. Jan PROVAZNÍK

Doctoral thesis

Artificial non-Gaussian operations and states for quantum information processing applications

Artificial nonlinearity for quantum information processing applications

Abstract:

Abstract:

Keywords

Thesis defence

Citation record

ISO 690-compliant citation record:

The right form of listing the thesis as a source quoted

Full text of thesis

Contents of on-line thesis archive

Other ways of accessing the text

Palacký University Olomouc

Theses on a related topic

Folders

Files

Co je jinak přidání souboru

Co je jinak další operace se soubory

Co je jinak pohled pro experty

Co je nové vyhledávání souborů

Co je nové rychlý přístup k souborům

Co se chystá