Two-local qubit Hamiltonians: when are they stoquastic?

Klassen, Joel; Terhal, Barbara M.

doi:10.22331/q-2019-05-06-139

Cited by 28 publications

(63 citation statements)

References 25 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…According to reference [40], a two-local two-qubit Hamiltonian of the form H = h xI σ σ σ x,1 + h Ix σ σ σ x,2 + h zI σ σ σ z,1 + h Iz σ σ σ z,2 + +h xx σ σ σ x,1 σ σ σ x,2 + h yy σ σ σ y,1 σ σ σ y,2 + h zz σ σ σ z,1 σ σ σ z,2…”

Section: Figureunclassified

Effective Hamiltonians for interacting superconducting qubits: local basis reduction and the Schrieffer–Wolff transformation

Consani

Warburton

2020

New J. Phys.

View full text Add to dashboard Cite

An open question in designing superconducting quantum circuits is how best to reduce the full circuit Hamiltonian which describes their dynamics to an effective two-level qubit Hamiltonian which is appropriate for manipulation of quantum information. Despite advances in numerical methods to simulate the spectral properties of multi-element superconducting circuits[1, 2, 3], the literature lacks a consistent and effective method of determining the effective qubit Hamiltonian. Here we address this problem by introducing a novel local basis reduction method. This method does not require any ad hoc assumption on the structure of the Hamiltonian such as its linear response to applied fields. We numerically benchmark the local basis reduction method against other Hamiltonian reduction methods in the literature and show that it is applicable over a wider parameter range, particularly for superconducting qubits with reduced anharmonicity, including the capacitively-shunted flux qubit. By combining the local basis reduction method with the Schrieffer-Wolff transformation we further extend its applicability to systems of interacting qubits and use it to extract both non-stoquastic two-qubit Hamiltonians and three-local interaction terms in three-qubit Hamiltonians. arXiv:1912.00464v1 [quant-ph] 1 Dec 2019

show abstract

Section: Figureunclassified

Effective Hamiltonians for interacting superconducting qubits: local basis reduction and the Schrieffer–Wolff transformation

Consani

Warburton

2020

New J. Phys.

View full text Add to dashboard Cite

show abstract

“…Otherwise, representation of the basis vectors requires exponential resources. A Hamiltonian is stoquastic if there exists a local basis such that all its off-diagonal elements are real and nonpositive [14][15][16]. A positive off-diagonal element would cause negative transition probabilities, which cannot be simulated by stochastic processes.…”

Section: Introductionmentioning

confidence: 99%

Demonstration of a Nonstoquastic Hamiltonian in Coupled Superconducting Flux Qubits

Özfidan¹,

Deng²,

Smirnov³

et al. 2020

Phys. Rev. Applied

View full text Add to dashboard Cite

Hamiltonian-based quantum computation is a class of quantum algorithms in which the problem is encoded in a Hamiltonian and the evolution is performed by a continuous transformation of the Hamiltonian. Universal adiabatic quantum computing, quantum simulation, and quantum annealing are examples of such algorithms. Up to now, all implementations of this approach have been limited to qubits coupled via a single degree of freedom. This gives rise to a stoquastic Hamiltonian that has no sign problem in quantum Monte Carlo simulations. In this paper, we report implementation and measurements of two superconducting flux qubits coupled via two canonically conjugate degrees of freedom-charge and flux-to achieve a nonstoquastic Hamiltonian. We perform microwave spectroscopy to extract circuit parameters and show that the charge coupling manifests itself as a σ y σ y interaction in the computational basis. We observe destructive interference in quantum coherent oscillations between the computational basis states of the two-qubit system. Finally, we show that the extracted Hamiltonian is nonstoquastic over a wide range of parameters.

show abstract

“…This capability would then enable the experimental exploration of a number of potentially significant ideas that until now have remained out of reach of available physical qubit hardware. These include, for example: the use of strong, non-stoquastic driver Hamiltonians in quantum annealing [42][43][44][45][46][47][48][49] and quantum simulation [13][14][15][16][17]; Hamiltonians required for Hamiltonian and holonomic computing paradigms [18][19][20][21]9]; and engineered emulation of the full quantum Heisenberg model. If combined with one or more of the proposed schemes for realizing static [99][100][101][102] or pulsed [64] multiqubit interactions, an even wider range of possibilities would become accessible, including adiabatic topological quantum computation [12], adiabatic quantum chemistry [22][23][24], and quantum error suppression [8,9].…”

Section: Resultsmentioning

confidence: 99%

“…In particular, although these qubits are well-suited to emulation of the simpler, transverse-field Ising spin (which interacts with other spins only via its z-component), controllable vector spin interactions of the kind we discuss here are fundamentally beyond their capability. A direct consequence of this is an inability to realize the controllable 'non-stoquastic' qubit interactions [40] that have been the subject of intense interest in recent years [41][42][43][44][45][46][47][48][49][50][51][52], due to the potentially transformative role such interactions may have on the computational power of quantum annealing. Exploring this capability is of paramount importance, in light of the fact that while quantum annealing has many potential applications, its ability to enable beyond-classical capabilities has yet to be fully understood or even conclusively shown.…”

mentioning

confidence: 99%

Superconducting qubit circuit emulation of a vector spin-1/2

Kerman

2019

New J. Phys.

View full text Add to dashboard Cite

We propose a superconducting qubit that fully emulates a quantum spin-1/2, with an effective vector dipole moment whose three components obey the commutation relations of an angular momentum in the computational subspace. Each of these components of the dipole moment also couples approximately linearly to an independently-controllable external bias, emulating the linear Zeeman effect due to a fictitious, vector magnetic field over a broad range of effective total fields around zero. This capability, combined with established techniques for qubit coupling, should enable for the first time the direct, controllable hardware emulation of nearly arbitrary, interacting quantum spin-1/2 systems, including the canonical Heisenberg model. Furthermore, it constitutes a crucial step both towards realizing the full potential of quantum annealing, as well as exploring important quantum information processing capabilities that have so far been inaccessible to available hardware, such as quantum error suppression, Hamiltonian and holonomic quantum computing, and adiabatic quantum chemistry.Quantum spin-1/2 models serve as basic paradigms for a wide variety of physical systems in quantum statistical mechanics and many-body physics, and are among the most highly studied in the context of quantum phase transitions and topological order [1][2][3][4]. In addition, since the spin-1/2 in a magnetic field is one of the simplest realizations of a qubit, many quantum information processing paradigms draw heavily on concepts which originated from or are closely related to quantum magnetism. For example, quantum spin-1/2 language is used to describe nearly all of the constructions underlying quantum error-correction [5-7] and error-suppression [8,9] methods. It is also the most commonly-used framework for specifying engineered Hamiltonians in many other quantum protocols such as quantum annealing [10,11], adiabatic topological quantum computing [12], quantum simulation [13-17], Hamiltonian and holonomic quantum computing [9,[18][19][20][21], and quantum chemistry [22][23][24].The conventional method for simulating vector spin-1/2 Hamiltonians is based on the 'gate-model' quantum simulation paradigm, and uses pulsed, high-speed sequences of discrete, non-commuting gate operations [25-27] to approximate time-evolution under a desired Hamiltonian [28,29]. In this paradigm, simulating a different Hamiltonian simply requires reprogramming the hardware with a different sequence of gates, a desirable property so long as the error introduced by the discretization can be kept sufficiently low. Unfortunately, this becomes increasingly difficult as the required spin interactions become stronger and/or more complex, since for a fixed gate duration 1 , the discretization error grows both with the strength of the spinspin interactions, and with the number of mutually-noncommuting terms they contain. In addition, gate-based implementation necessarily implies that the system occupies Hilbert space far above its ground state, and the resulting information ...

show abstract

Two-local qubit Hamiltonians: when are they stoquastic?

Cited by 28 publications

References 25 publications

Effective Hamiltonians for interacting superconducting qubits: local basis reduction and the Schrieffer–Wolff transformation

Effective Hamiltonians for interacting superconducting qubits: local basis reduction and the Schrieffer–Wolff transformation

Demonstration of a Nonstoquastic Hamiltonian in Coupled Superconducting Flux Qubits

Superconducting qubit circuit emulation of a vector spin-1/2

Contact Info

Product

Resources

About