Your search keyword '"Shannon Ray"' showing total 8 results

1. A Differential-Geometric Approach to Quantum Ignorance Consistent with Entropic Properties of Statistical Mechanics

Author

Shannon Ray, Paul M. Alsing, Carlo Cafaro, and H S. Jacinto

Subjects

Quantum Physics, differential geometry, entanglement entropy, quantum information, statistical physics, coarse-graining, many-body systems, ignorance, thermalization, Lie groups, General Physics and Astronomy, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

In this paper, we construct the metric tensor and volume for the manifold of purifications associated with an arbitrary reduced density operator $\rho_S$. We also define a quantum coarse-graining (CG) to study the volume where macrostates are the manifolds of purifications, which we call surfaces of ignorance (SOI), and microstates are the purifications of $\rho_S$. In this context, the volume functions as a multiplicity of the macrostates that quantifies the amount of information missing from $\rho_S$. Using examples where the SOI are generated using representations of $SU(2)$, $SO(3)$, and $SO(N)$, we show two features of the CG. (1) A system beginning in an atypical macrostate of smaller volume evolves to macrostates of greater volume until it reaches the equilibrium macrostate in a process in which the system and environment become strictly more entangled, and (2) the equilibrium macrostate takes up the vast majority of the coarse-grainied space especially as the dimension of the total system becomes large. Here, the equilibrium macrostate corresponds to maximum entanglement between system and environment. To demonstrate feature (1) for the examples considered, we show that the volume behaves like the von Neumann entropy in that it is zero for pure states, maximal for maximally mixed states, and is a concave function w.r.t the purity of $\rho_S$. These two features are essential to typicality arguments regarding thermalization and Boltzmann's original CG., Comment: 12 pages, 10 figures. arXiv admin note: text overlap with arXiv:2111.07836

Published

2022

2. Optimal-speed unitary quantum time evolutions and propagation of light with maximal degree of coherence

Author

Carlo Cafaro, Shannon Ray, and Paul M. Alsing

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

It is recognized that Grover arrived at his original quantum search algorithm inspired by his comprehension of the interference of classical waves originating from an array of antennas. It is also known that quantum-mechanical characterization of electromagnetic radiation is isomorphic to the treatment of the orientation of a spin-1/2 particle. In this paper, motivated by Grover's original intuition and starting from this mathematical equivalence, we present a quantitative link between the geometry of time-independent optimal-speed Hamiltonian evolutions on the Bloch sphere and the geometry of intensity-preserving propagation of light with maximal degree of coherence on the Poincar\'e sphere. Finally, identifying interference as the fundamental physical ingredient underlying both physical phenomena, we propose that our work can provide in retrospect a quantitative geometric background underlying Grover's powerful intuition., Comment: 22 pages, 1 figure, 3 tables

Published

2021

3. Geometric aspects of analog quantum search evolutions

Author

Carlo Cafaro, Shannon Ray, and Paul M. Alsing

Subjects

Physics, Quantum Physics, Perspective (geometry), Geodesic, Geometric analysis, Quantum state, Projective Hilbert space, FOS: Physical sciences, Statistical physics, Quantum Physics (quant-ph), Quantum, Quantum evolution, Quantum computer

Abstract

We use geometric concepts originally proposed by Anandan and Aharonov to show that the Farhi-Gutmann time optimal analog quantum search evolution between two orthogonal quantum states is characterized by unit efficiency dynamical trajectories traced on a projective Hilbert space. In particular, we prove that these optimal dynamical trajectories are the shortest geodesic paths joining the initial and the final states of the quantum evolution. In addition, we verify they describe minimum uncertainty evolutions specified by an uncertainty inequality that is tighter than the ordinary time-energy uncertainty relation. We also study the effects of deviations from the time optimality condition from our proposed Riemannian geometric perspective. Furthermore, after pointing out some physically intuitive aspects offered by our geometric approach to quantum searching, we mention some practically relevant physical insights that could emerge from the application of our geometric analysis to more realistic time-dependent quantum search evolutions. Finally, we briefly discuss possible extensions of our work to the geometric analysis of the efficiency of thermal trajectories of relevance in quantum computing tasks., 14 pages, 1 figure, 1 table

Published

2020

4. Quantifying Tri-partite Entanglement with Entropic Correlations

Author

Christopher C. Tison, Shannon Ray, James Schneeloch, Paul M. Alsing, and Michael L. Fanto

Subjects

Physics, Multipartite, Quantum Physics, Photon, FOS: Physical sciences, Quantum entanglement, Statistical physics, Quantum Physics (quant-ph), Parametric statistics

Abstract

We show how to quantify tri-partite entanglement using entropies derived from experimental correlations. We use a multi-partite generalization of the entanglement of formation that is greater than zero if and only if the state is genuinely multi-partite entangled. We develop an entropic witness for tripartite entanglement, and show that the degree of violation of this witness places a lower limit on the tripartite entanglement of formation. We test our results in the three-qubit regime using the GHZ-Werner state and the W-Werner state, and in the high-dimensional pure-state regime using the triple-Gaussian wavefunction describing the spatial and energy-time entanglement in photon triplets generated in third-order spontaneous parametric down-conversion. In addition, we discuss the challenges in quantifying the entanglement for progressively larger numbers of parties, and give both entropic and target-state-based witnesses of multi-partite entanglement that circumvent this issue., 14 pages, 6 figures (removed inequality (formerly appendix B4) due to typo)

Published

2020

5. Maximum advantage of quantum illumination

Author

Paul M. Alsing, James Schneeloch, Shannon Ray, and Christopher C. Tison

Subjects

Physics, Quantum Physics, Bell state, Measure (physics), FOS: Physical sciences, State (functional analysis), Quantum channel, 01 natural sciences, 010305 fluids & plasmas, Dimension (vector space), Quantum state, 0103 physical sciences, Quantum illumination, Statistical physics, Quantum information, Quantum Physics (quant-ph), 010306 general physics

Abstract

Discriminating between quantum states is a fundamental problem in quantum information protocols. The optimum approach saturates the Helstrom bound, which quantifies the unavoidable error probability of mistaking one state for another. Computing the error probability directly requires complete knowledge and diagonalization of the density matrices describing these states. Both of these fundamental requirements become impractically difficult to obtain as the dimension of the states grow large. In this article, we analyze quantum illumination as a quantum channel discrimination protocol and circumvent these issues by using the normalized Hilbert-Schmidt inner product as a measure of distinguishability. Using this measure, we show that the greatest advantage gained by quantum illumination over conventional illumination occurs when one uses a Bell state., Comment: 6 pages, 1 figure

Published

2019

6. Wang and Yau's Quasi-Local Energy for an Extreme Kerr Spacetime

Author

Warner A. Miller, Shing-Tung Yau, Mu-Tao Wang, and Shannon Ray

Subjects

Physics, Physics and Astronomy (miscellaneous), Spacetime, 010308 nuclear & particles physics, Boundary (topology), FOS: Physical sciences, Function (mathematics), General Relativity and Quantum Cosmology (gr-qc), Space (mathematics), 01 natural sciences, General Relativity and Quantum Cosmology, Critical point (mathematics), 0103 physical sciences, Minkowski space, 010306 general physics, Energy (signal processing), Mathematical physics, Energy functional

Abstract

There exist constant radial surfaces, $\mathcal{S}$, that may not be globally embeddable in $\mathbb{R}^3$ for Kerr spacetimes with $a>\sqrt{3}M/2$. To compute the Brown and York (B-Y) quasi-local energy (QLE), one must isometrically embed $\mathcal{S}$ into $\mathbb{R}^3$. On the other hand, the Wang and Yau (W-Y) QLE embeds $\mathcal{S}$ into Minkowski space. In this paper, we examine the W-Y QLE for surfaces that may or may not be globally embeddable in $\mathbb{R}^3$. We show that their energy functional, $E[\tau]$, has a critical point at $\tau=0$ for all constant radial surfaces in $t=constant$ hypersurfaces using Boyer-Lindquist coordinates. For $\tau=0$, the W-Y QLE reduces to the B-Y QLE. To examine the W-Y QLE in these cases, we write the functional explicitly in terms of $\tau$ under the assumption that $\tau$ is only a function of $\theta$. We then use a Fourier expansion of $\tau\left(\theta\right)$ to explore the values of $E[\tau\left(\theta\right)]$ in the space of coefficients. From our analysis, we discovered an open region of complex values for $E[\tau\left(\theta\right)]$. We also study the physical properties of the smallest real value of $E[\tau\left(\theta\right)]$, which lies on the boundary separating real and complex energies., Comment: 25 pages, 10 figures

Published

2017

7. Distributed mean curvature on a discrete manifold for Regge calculus

Author

Shannon Ray, Warner A. Miller, and Rory Conboye

Subjects

Physics, Pointwise, Pure mathematics, Mean curvature, Physics and Astronomy (miscellaneous), Simplicial manifold, FOS: Physical sciences, Regge calculus, General Relativity and Quantum Cosmology (gr-qc), Curvature, General Relativity and Quantum Cosmology, Manifold, Mathematics::Differential Geometry, Discrete differential geometry, Distribution (differential geometry)

Abstract

The integrated mean curvature of a simplicial manifold is well understood in both Regge Calculus and Discrete Differential Geometry. However, a well motivated pointwise definition of curvature requires a careful choice of volume over which to uniformly distribute the local integrated curvature. We show that hybrid cells formed using both the simplicial lattice and its circumcentric dual emerge as a remarkably natural structure for the distribution of this local integrated curvature. These hybrid cells form a complete tessellation of the simplicial manifold, contain a geometric orthonormal basis, and are also shown to give a pointwise mean curvature with a natural interpretation as a fractional rate of change of the normal vector.

Published

2015

8. Simplicial Ricci Flow: An Example of a Neck Pinch Singularity in 3D

Author

Seth Lloyd, Shing-Tung Yau, Matthew Corne, David Xianfeng Gu, Warner A. Miller, Paul M. Alsing, Shannon Ray, Massachusetts Institute of Technology. Department of Mechanical Engineering, and Lloyd, Seth

Subjects

Physics, Mathematics - Differential Geometry, Frustum, 53C20 (Primary), 58B20 (Secondary), Mathematical analysis, Rotational symmetry, Discrete geometry, FOS: Physical sciences, Ricci flow, General Relativity and Quantum Cosmology (gr-qc), General Relativity and Quantum Cosmology, Singularity, Differential Geometry (math.DG), Piecewise, FOS: Mathematics, Mirror symmetry, Axial symmetry

Abstract

We examine a Type-1 neck pinch singularity in simplicial Ricci flow (SRF) for an axisymmetric piecewise flat 3-dimensional geometry with 3-sphere topology. SRF was recently introduced as an unstructured mesh formulation of Hamilton's Ricci flow (RF). It describes the RF of a piecewise-flat simplicial geometry. In this paper, we apply the SRF equations to a representative double-lobed axisymmetric piecewise flat geometry with mirror symmetry at the neck similar to the geometry studied by Angenent and Knopf (A-K). We choose a specific radial profile and compare the SRF equations with the corresponding finite-difference solution of the continuum A-K RF equations. The piecewise-flat 3-geometries considered here are built of isosceles-triangle-based frustum blocks. The axial symmetry of this model allows us to use frustum blocks instead of tetrahedra. The 2-sphere cross-sectional geometries in our model are regular icosahedra. We demonstrate that, under a suitably-pinched initial geometry, the SRF equations for this relatively low-resolution discrete geometry yield the canonical Type-1 neck pinch singularity found in the corresponding continuum solution. We adaptively remesh during the evolution to keep the circumcentric dual lattice well-centered. Without such remeshing, we cannot evolve the discrete geometry to neck pinch. We conclude with a discussion of future generalizations and tests of this SRF model., Comment: 15 pages, 7 figures, submitted to Geometry, Imaging and Computation, minor revisions

Published

2013