Generalizations of entanglement based on coherent states and convex sets

Barnum, Howard; Knill, Emanuel; Ortíz, Gerardo; Viola, Lorenza

doi:10.1103/physreva.68.032308

Cited by 131 publications

(222 citation statements)

References 72 publications

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“…3 can be expressed in terms of generalized entanglement [1,14,21]. A pure state is generalized unentangled (GU) with respect to a preferred set O of observables if it is extremal among states considered as linear functionals on O, otherwise it is generalized entangled.…”

Section: Theorem 3 For Both Lqc Measurement Schemes the Results Of Anmentioning

confidence: 99%

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Efficient Solvability of Hamiltonians and Limits on the Power of Some Quantum Computational Models

et al. 2006

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We consider quantum computational models defined via a Lie-algebraic theory. In these models, specified initial states are acted on by Lie-algebraic quantum gates and the expectation values of Lie algebra elements are measured at the end. We show that these models can be efficiently simulated on a classical computer in time polynomial in the dimension of the algebra, regardless of the dimension of the Hilbert space where the algebra acts. Similar results hold for the computation of the expectation value of operators implemented by a gatesequence. We introduce a Lie-algebraic notion of generalized mean-field Hamiltonians and show that they are efficiently (exactly) solvable by means of a Jacobi-like diagonalization method. Our results generalize earlier ones on fermionic linear optics computation and provide insight into the source of the power of the conventional model of quantum computation. Quantum models of computation are widely believed to be more powerful than classical ones. Although this has been shown to be true in a few cases, it is still important to determine when a quantum algorithm for a given problem is more resource efficient than any classical one, or, conversely, when a classical algorithm is just as efficient as any quantum counterpart. In general, one needs to know whether it is worth investing in building a quantum computer (QC) and what is required for success. In this paper, we show close connections between these issues and the efficient (or exact) solvability of Hamiltonians. In particular, we show that a class of quantum models we call generalized mean-field Hamiltonians (GMFHs) [1] is efficiently solvable and furthermore does not provide a stronger-than-classical model of computation: A quantum device engineered to have dynamical gates generated by Hamiltonians from such a set cannot directly simulate universal efficient quantum computation and can be efficiently simulated by a classical computer (CC).An algorithm is a sequence of elementary instructions that solves instances of a problem. It is said to be efficient if the resources required to solve problem instances of size N are polynomial in N (poly(N )) resources. Typically, the size of a problem instance is the number of bits required to represent it, and the relevant resources are time and space. In the last few years it has been shown that many pure-state quantum algorithms can be efficiently simulated on a CC when the extent of entanglement is limited (e.g., [2,3]) or when the quantum gates available are far from allowing us to build a set of universal gates [4,5,6]. Here, we focus on a Lie algebraic analysis to obtain other situations where quantum algorithms can be efficiently simulated by CCs. The so-called generalized coherent states (GCSs) [7] play a decisive role in our analysis.The algorithms considered here make use of the Liealgebraic model of quantum computing (LQC). An LQC algorithm begins with the specification of a semisimple, compact M -dimensional real Lie algebraĥ of skew-Hermitian operators acting on a finite-...

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Section: Theorem 3 For Both Lqc Measurement Schemes the Results Of Anmentioning

confidence: 99%

mentioning

confidence: 99%

Efficient Solvability of Hamiltonians and Limits on the Power of Some Quantum Computational Models

et al. 2006

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“…In a manner similar to [17], we will consider a redefinition of the single-particle-state space away from the "quantum" version, thereby giving a different notion of "separability" under which one can apply the algorithm of [10]. As a starting point for our generalized state spaces we will use the following characterization of the quantum set Q d of dimension d singleparticle states.…”

Section: Generalized Notions Of Entanglement and Application To mentioning

confidence: 99%

“…The aim of the present work is to use a generalized notion of entanglement [17] (in a sense described in the next section) to apply a modified version of the Harrow and Nielsen method to devices where there are restrictions on the measurements available. Such restrictions arise naturally in fault tolerant quantum computation for two reasons.…”

Section: Introductionmentioning

confidence: 99%

“…It also motivates the construction of generalized probabilistic theories [18] that are inspired by fault tolerant quantum computation schemes (although in our primary case the generalized theory turns out to be very close to a classical theory), and provides regimes of classically tractable noisy quantum evolution that appear to fall outside the scope of existing methods. It also falls under the program initiated in [17] to investigate so-called generalized notions of entanglement, and motivates some interesting questions regarding the contrast between different forms of generalized multiparty entanglement.…”

Section: Introductionmentioning

confidence: 99%

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Generalized state spaces and nonlocality in fault-tolerant quantum-computing schemes

Ratanje

Virmani

2011

Phys. Rev. A

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We develop connections between generalized notions of entanglement and quantum computational devices where the measurements available are restricted, either because they are noisy and/or because by design they are only along Pauli directions. By considering restricted measurements one can (by considering the dual positive operators) construct single-particle-state spaces that are different to the usual quantum-state space. This leads to a modified notion of entanglement that can be very different to the quantum version (for example, Bell states can become separable). We use this approach to develop alternative methods of classical simulation that have strong connections to the study of nonlocal correlations: we construct noisy quantum computers that admit operations outside the Clifford set and can generate some forms of multiparty quantum entanglement, but are otherwise classical in that they can be efficiently simulated classically and cannot generate nonlocal statistics. Although the approach provides new regimes of noisy quantum evolution that can be efficiently simulated classically, it does not appear to lead to significant reductions of existing upper bounds to fault tolerance thresholds for common noise models.

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Emergent Timescales in Entangled Quantum Dynamics of Ultracold Molecules in Optical Lattices

Wall

2015

Quantum Many-Body Physics of Ultracold Molecules in Optical Lattices

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We derive a novel lattice Hamiltonian, the Molecular Hubbard Hamiltonian (MHH), which describes the essential many body physics of closed-shell ultracold heteronuclear molecules in their absolute ground state in a quasi-one-dimensional optical lattice. The MHH is explicitly time-dependent, making a dynamic generalization of the concept of quantum phase transitions necessary. Using the Time-Evolving Block Decimation (TEBD) algorithm to study entangled dynamics, we demonstrate that, in the case of hard core bosonic molecules at half filling, the MHH exhibits an emergent time scale over which spatial entanglement grows, crystalline order appears, and oscillations between rotational states self-damp into an asymptotic superposition. We show that this time scale is a non-monotonic function of the physical parameters describing the lattice. We also point out that experimental mapping of the static phase boundaries of the MHH can be used to measure the molecular polarizability tensor.whereâ iJM destroys a bosonic or fermionic molecule in the |E; JM state (defined below) on the i th lattice site, and the bracket notation . . . denotes that the sum is taken over nearest neighbors. The first term in Eq. (1) corresponds to hopping both between sites and molecular rotational states with quantum numbers J, M. The second term represents the rotational energy along with rotational statedependent energy differences due to a DC electric field. The third term corresponds to an AC electric field, making this a driven system. The fourth term corresponds to electric dipole-dipole interactions. Entangled Quantum Dynamics

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Generalizations of entanglement based on coherent states and convex sets

Cited by 131 publications

References 72 publications

Efficient Solvability of Hamiltonians and Limits on the Power of Some Quantum Computational Models

Efficient Solvability of Hamiltonians and Limits on the Power of Some Quantum Computational Models

Generalized state spaces and nonlocality in fault-tolerant quantum-computing schemes

Emergent Timescales in Entangled Quantum Dynamics of Ultracold Molecules in Optical Lattices

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