QUANTUM ESTIMATION OF RELATIVE INFORMATION

We derive optimal schemes for preparation and estimation of relational degrees of freedom between two quantum systems. We specifically analyze the case of rotation parameters representing relative angles between elements of the SU(2) symmetry group. Our estimation procedure does not assume prior knowledge of the absolute spatial orientation of the systems and as such does not require information on the underlying classical reference frame in which the states are prepared.

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Quantum reference frames for general symmetry groups

Quantum ◽

10.22331/q-2020-11-30-367 ◽

2020 ◽

Vol 4 ◽

pp. 367

Author(s):

Anne-Catherine de la Hamette ◽

Thomas D. Galley

Keyword(s):

Symmetry Group ◽

Reference Frame ◽

Direct Product ◽

Reference Frames ◽

Quantum Systems ◽

Coordinate Systems ◽

General Operator ◽

General Symmetry ◽

Regular Representations ◽

Wigner’S Friend

A fully relational quantum theory necessarily requires an account of changes of quantum reference frames, where quantum reference frames are quantum systems relative to which other systems are described. By introducing a relational formalism which identifies coordinate systems with elements of a symmetry group G, we define a general operator for reversibly changing between quantum reference frames associated to a group G. This generalises the known operator for translations and boosts to arbitrary finite and locally compact groups, including non-Abelian groups. We show under which conditions one can uniquely assign coordinate choices to physical systems (to form reference frames) and how to reversibly transform between them, providing transformations between coordinate systems which are `in a superposition' of other coordinate systems. We obtain the change of quantum reference frame from the principles of relational physics and of coherent change of reference frame. We prove a theorem stating that the change of quantum reference frame consistent with these principles is unitary if and only if the reference systems carry the left and right regular representations of G. We also define irreversible changes of reference frame for classical and quantum systems in the case where the symmetry group G is a semi-direct product G=N⋊P or a direct product G=N×P, providing multiple examples of both reversible and irreversible changes of quantum reference system along the way. Finally, we apply the relational formalism and changes of reference frame developed in this work to the Wigner's friend scenario, finding similar conclusions to those in relational quantum mechanics using an explicit change of reference frame as opposed to indirect reasoning using measurement operators.

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Multiparticle quantum plasmonics

Nanophotonics ◽

10.1515/nanoph-2019-0517 ◽

2020 ◽

Vol 9 (6) ◽

pp. 1243-1269 ◽

Cited By ~ 2

Author(s):

Chenglong You ◽

Apurv Chaitanya Nellikka ◽

Israel De Leon ◽

Omar S. Magaña-Loaiza

Keyword(s):

Quantum Dynamics ◽

Degrees Of Freedom ◽

Single Photon ◽

Quantum Systems ◽

Many Body ◽

Statistical Fluctuations ◽

Quantum Plasmonics ◽

Control Of Quantum Systems ◽

Multiparticle Systems ◽

Quantum Photonics

AbstractA single photon can be coupled to collective charge oscillations at the interfaces between metals and dielectrics forming a single surface plasmon. The electromagnetic near-fields induced by single surface plasmons offer new degrees of freedom to perform an exquisite control of complex quantum dynamics. Remarkably, the control of quantum systems represents one of the most significant challenges in the field of quantum photonics. Recently, there has been an enormous interest in using plasmonic systems to control multiphoton dynamics in complex photonic circuits. In this review, we discuss recent advances that unveil novel routes to control multiparticle quantum systems composed of multiple photons and plasmons. We describe important properties that characterize optical multiparticle systems such as their statistical quantum fluctuations and correlations. In this regard, we discuss the role that photon-plasmon interactions play in the manipulation of these fundamental properties for multiparticle systems. We also review recent works that show novel platforms to manipulate many-body light-matter interactions. In this spirit, the foundations that will allow nonexperts to understand new perspectives in multiparticle quantum plasmonics are described. First, we discuss the quantum statistical fluctuations of the electromagnetic field as well as the fundamentals of plasmonics and its quantum properties. This discussion is followed by a brief treatment of the dynamics that characterize complex multiparticle interactions. We apply these ideas to describe quantum interactions in photonic-plasmonic multiparticle quantum systems. We summarize the state-of-the-art in quantum devices that rely on plasmonic interactions. The review is concluded with our perspective on the future applications and challenges in this burgeoning field.

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Quasi-Lie Brackets and the Breaking of Time-Translation Symmetry for Quantum Systems Embedded in Classical Baths

Symmetry ◽

10.3390/sym10100518 ◽

2018 ◽

Vol 10 (10) ◽

pp. 518 ◽

Cited By ~ 9

Author(s):

Alessandro Sergi ◽

Gabriel Hanna ◽

Roberto Grimaudo ◽

Antonino Messina

Keyword(s):

Constant Temperature ◽

Degrees Of Freedom ◽

Open Quantum Systems ◽

Hamiltonian Dynamics ◽

Quantum Systems ◽

Classical Dynamics ◽

Open Quantum ◽

Time Translation ◽

Translation Symmetry ◽

Lie Brackets

Many open quantum systems encountered in both natural and synthetic situations are embedded in classical-like baths. Often, the bath degrees of freedom may be represented in terms of canonically conjugate coordinates, but in some cases they may require a non-canonical or non-Hamiltonian representation. Herein, we review an approach to the dynamics and statistical mechanics of quantum subsystems embedded in either non-canonical or non-Hamiltonian classical-like baths which is based on operator-valued quasi-probability functions. These functions typically evolve through the action of quasi-Lie brackets and their associated Quantum-Classical Liouville Equations, or through quasi-Lie brackets augmented by dissipative terms. Quasi-Lie brackets possess the unique feature that, while conserving the energy (which the Noether theorem links to time-translation symmetry), they violate the time-translation symmetry of their algebra. This fact can be heuristically understood in terms of the dynamics of the open quantum subsystem. We then describe an example in which a quantum subsystem is embedded in a bath of classical spins, which are described by non-canonical coordinates. In this case, it has been shown that an off-diagonal open-bath geometric phase enters into the propagation of the quantum-classical dynamics. Next, we discuss how non-Hamiltonian dynamics may be employed to generate the constant-temperature evolution of phase space degrees of freedom coupled to the quantum subsystem. Constant-temperature dynamics may be generated by either a classical Langevin stochastic process or a Nosé–Hoover deterministic thermostat. These two approaches are not equivalent but have different advantages and drawbacks. In all cases, the calculation of the operator-valued quasi-probability function allows one to compute time-dependent statistical averages of observables. This may be accomplished in practice using a hybrid Molecular Dynamics/Monte Carlo algorithms, which we outline herein.

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Structure of canonical variables in the theory of quantum systems with finitely and infinitely many degrees of freedom

Theoretical and Mathematical Physics ◽

10.1007/bf01037188 ◽

1974 ◽

Vol 19 (1) ◽

pp. 325-331

Author(s):

N. V. Borisov

Keyword(s):

Degrees Of Freedom ◽

Quantum Systems ◽

Canonical Variables

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Estimating kinetic mechanisms with prior knowledge II: Behavioral constraints and numerical tests

The Journal of General Physiology ◽

10.1085/jgp.201711912 ◽

2018 ◽

Vol 150 (2) ◽

pp. 339-354 ◽

Cited By ~ 6

Author(s):

Marco A. Navarro ◽

Autoosa Salari ◽

Mirela Milescu ◽

Lorin S. Milescu

Keyword(s):

Prior Knowledge ◽

Estimation Procedure ◽

Kinetic Mechanism ◽

Arbitrary Parameter ◽

Linear Parameter ◽

Open Probability ◽

Behavioral Constraints ◽

Kinetic Mechanisms ◽

Mathematical Relationships ◽

Optimization Mechanism

Kinetic mechanisms predict how ion channels and other proteins function at the molecular and cellular levels. Ideally, a kinetic model should explain new data but also be consistent with existing knowledge. In this two-part study, we present a mathematical and computational formalism that can be used to enforce prior knowledge into kinetic models using constraints. Here, we focus on constraints that quantify the behavior of the model under certain conditions, and on constraints that enforce arbitrary parameter relationships. The penalty-based optimization mechanism described here can be used to enforce virtually any model property or behavior, including those that cannot be easily expressed through mathematical relationships. Examples include maximum open probability, use-dependent availability, and nonlinear parameter relationships. We use a simple kinetic mechanism to test multiple sets of constraints that implement linear parameter relationships and arbitrary model properties and behaviors, and we provide numerical examples. This work complements and extends the companion article, where we show how to enforce explicit linear parameter relationships. By incorporating more knowledge into the parameter estimation procedure, it is possible to obtain more realistic and robust models with greater predictive power.

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Cluster state quantum computation for many-level systems

Quantum Information and Computation ◽

10.26421/qic7.3-2 ◽

2007 ◽

Vol 7 (3) ◽

pp. 184-208

Author(s):

W. Hall

Keyword(s):

Quantum Computation ◽

Degrees Of Freedom ◽

Cluster State ◽

Quantum Systems ◽

Explicit Description ◽

State Model ◽

Mutually Unbiased Bases ◽

Large Set ◽

Adaptive Computation ◽

Complete Framework

The cluster state model for quantum computation [Phys. Rev. Lett. \textbf{86}, 5188] outlines a scheme that allows one to use measurement on a large set of entangled quantum systems in what is known as a cluster state to undertake quantum computations. The model itself and many works dedicated to it involve using entangled qubits. In this paper we consider the issue of using entangled qudits instead. We present a complete framework for cluster state quantum computation using qudits, which not only contains the features of the original qubit model but also contains the new idea of adaptive computation: via a change in the classical computation that helps to correct the errors that are inherent in the model, the implemented quantum computation can be changed. This feature arises through the extra degrees of freedom that appear when using qudits. Finally, for prime dimensions, we give a very explicit description of the model, making use of mutually unbiased bases.

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Quantum clocks and the temporal localisability of events in the presence of gravitating quantum systems

Nature Communications ◽

10.1038/s41467-020-16013-1 ◽

2020 ◽

Vol 11 (1) ◽

Cited By ~ 4

Author(s):

Esteban Castro-Ruiz ◽

Flaminia Giacomini ◽

Alessio Belenchia ◽

Časlav Brukner

Keyword(s):

Reference Frame ◽

Reference Frames ◽

Quantum Systems ◽

Indefinite Metric ◽

Causal Order ◽

Quantum Operations ◽

Unitary Dilation ◽

Local Quantum ◽

Fixed Space ◽

Quantum Clocks

AbstractThe standard formulation of quantum theory relies on a fixed space-time metric determining the localisation and causal order of events. In general relativity, the metric is influenced by matter, and is expected to become indefinite when matter behaves quantum mechanically. Here, we develop a framework to operationally define events and their localisation with respect to a quantum clock reference frame, also in the presence of gravitating quantum systems. We find that, when clocks interact gravitationally, the time localisability of events becomes relative, depending on the reference frame. This relativity is a signature of an indefinite metric, where events can occur in an indefinite causal order. Even if the metric is indefinite, for any event we can find a reference frame where local quantum operations take their standard unitary dilation form. This form is preserved when changing clock reference frames, yielding physics covariant with respect to quantum reference frame transformations.

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State-independent contextuality in classical light

Scientific Reports ◽

10.1038/s41598-019-51250-5 ◽

2019 ◽

Vol 9 (1) ◽

Cited By ~ 1

Author(s):

Tao Li ◽

Qiang Zeng ◽

Xiong Zhang ◽

Tian Chen ◽

Xiangdong Zhang

Keyword(s):

Degrees Of Freedom ◽

Information Science ◽

Quantum Systems ◽

Optical Systems ◽

Quantum Information Science ◽

Independent Manner ◽

Classical Counterpart ◽

Information Processes ◽

Fundamental Phenomenon ◽

Application Prospects

AbstractState-independent contextuality is a fundamental phenomenon in quantum mechanics, which has been demonstrated experimentally in different systems in recent years. Here we show that such contextuality can also be simulated in classical optical systems. Using path and polarization degrees of freedom of classical optics fields, we have constructed the classical trit (cetrit), here the term ‘cetrit’ is the classical counterpart of a qutrit in quantum systems. Furthermore, in classical optical systems we have simulated the violations of several Yu-Oh-like noncontextual inequalities in a state-independent manner by implementing the projection measurements. Our results not only provide new physical insights into the contextuality and also show the application prospects of the concepts developed recently in quantum information science to classical optical systems and optical information processes.

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