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Multi-parameter optimisation of quantum optical systems

Slatyer, Harry James

Description

Quantum optical systems are poised to become integral components of technologies of the future. While there is growing commercial interest in these systems---for applications in information processing, secure communication and precision metrology---there remain significant technical challenges to overcome before widespread adoption is possible. In this thesis we consider the general problem of optimising quantum optical systems, with a focus on sensing and...[Show more]

dc.contributor.authorSlatyer, Harry James
dc.date.accessioned2018-08-08T01:09:53Z
dc.date.available2018-08-08T01:09:53Z
dc.identifier.otherb53532223
dc.identifier.urihttp://hdl.handle.net/1885/146120
dc.description.abstractQuantum optical systems are poised to become integral components of technologies of the future. While there is growing commercial interest in these systems---for applications in information processing, secure communication and precision metrology---there remain significant technical challenges to overcome before widespread adoption is possible. In this thesis we consider the general problem of optimising quantum optical systems, with a focus on sensing and information processing applications. We investigate four different classes of system with varying degrees of generality and complexity, and demonstrate four corresponding optimisation techniques. At the most specific end of the spectrum---where behaviour is best understood---we consider the problem of interferometric sensitivity enhancement, specifically in the context of long-baseline gravitational wave detectors. We investigate the use of an auxiliary optomechanical system to generate squeezed light exhibiting frequency-dependent quadrature rotation. Such rotation is necessary to evade the effect of quantum back action and achieve broadband sensitivity beyond the standard quantum limit. We find that a cavity optomechanical system is generally unsuitable for this purpose, since the quadrature rotation occurs in the opposite direction to that required for broadband sensitivity improvement. Next we introduce a general technique to engineer arbitrary optical spring potentials in cavity optomechanical systems. This technique has the potential to optimise many types of sensors relying on the optical spring effect. As an example, we show that this technique could yield an enhancement in sensitivity by a factor of 5 when applied to a certain gravitational sensor based on a levitated cavity mirror. We then consider a particular nanowire-based optomechanical system with potential applications in force sensing. We demonstrate a variety of ways to improve its sensitivity to transient forces. We first apply a non-stationary feedback cooling protocol to the system, and achieve an improvement in peak signal-to-noise ratio by a factor of 3, corresponding to a force resolution of 0.2fN. We then implement two non-stationary estimation schemes, which involve post-processing data taken in the absence of physical feedback cooling, to achieve a comparable enhancement in performance without the need for additional experimental complexity. Finally, to address the most complex of systems, we present a general-purpose machine learning algorithm capable of automatically modelling and optimising arbitrary physical systems without human input. To demonstrate the potential of the algorithm we apply it to a magneto-optical trap used for a quantum memory, and achieve an improvement in optical depth from 138 to 448. The four techniques presented differ significantly in their style and the types of systems to which they are applicable. Successfully harnessing the full range of such optimisation procedures will be vital in unlocking the potential of quantum optical systems in the technologies of the future
dc.language.isoen_AU
dc.subjectoptimisation
dc.subjectoptimization
dc.subjectquantum optics
dc.subjectmachine learning
dc.subjectneural network
dc.subjectLIGO
dc.subjectsqueezed light
dc.subjectquadrature rotation
dc.subjectkalman filter
dc.subjectoptical spring
dc.subjectoptomechanics
dc.subjectfeedback cooling
dc.titleMulti-parameter optimisation of quantum optical systems
dc.typeThesis (PhD)
local.contributor.supervisorLam, Ping Koy
local.contributor.supervisorcontactping.lam@anu.edu.au
dcterms.valid2018
local.description.notesthe author deposited 8/08/2018
local.type.degreeDoctor of Philosophy (PhD)
dc.date.issued2018
local.contributor.affiliationDepartment of Quantum Science, Research School of Physics and Engineering, The Australian National University
local.identifier.doi10.25911/5d651212b3842
local.mintdoimint
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