Compensating for the Effects of Decoherence in Quantum States
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Date
2019-01-01
Type of Work
Department
Physics
Program
Physics, Applied
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Distribution Rights granted to UMBC by the author.
Access limited to the UMBC community. Item may possibly be obtained via Interlibrary Loan thorugh a local library, pending author/copyright holder's permission.
This item is likely protected under Title 17 of the U.S. Copyright Law. Unless on a Creative Commons license, for uses protected by Copyright Law, contact the copyright holder or the author.
Access limited to the UMBC community. Item may possibly be obtained via Interlibrary Loan thorugh a local library, pending author/copyright holder's permission.
This item is likely protected under Title 17 of the U.S. Copyright Law. Unless on a Creative Commons license, for uses protected by Copyright Law, contact the copyright holder or the author.
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Abstract
Quantum information is a field with many potential applications in future technology. One of the major challenges in the practical implementation of quantum information protocols is the difficulty in synthesizing and maintaining controllable quantum systems. One of the reasons for this is because quantum systems are susceptible to decoherence that reduces the quality of the quantum state of a system. There have been several advances toward mitigating this decoherence such as the design of codes to combat errors due to incoherent quantum evolution, known as quantum error correction, and the design of novel quantum states that are less susceptible to decoherence. In this dissertations, we provide a rigorous analysis of the mechanisms that introduce decoherence into select quantum states and propose methods to compensate for it. We find that squeezing a macroscopic quantum optical state known as a Schr�dinger cat state can reduce the amount of decoherence introduced by optical parametric amplification. We also find that noiseless amplification can be used to compensate for decoherence due to polarization dependent loss in single-photonic polarization qubits. In the process of understanding decoherence and its compensation we also introduce new and exciting mathematical and physical concepts such as delta functions that admit complex arguments, known as the generalized delta function, and a noiseless attenuator made using an optical parametric amplifier.