Your search keyword '"E. Tolkacheva"' showing total 4 results

1. Entanglement in a Quantum Annealing Processor

Author

T. Lanting, A. J. Przybysz, A. Yu. Smirnov, F. M. Spedalieri, M. H. Amin, A. J. Berkley, R. Harris, F. Altomare, S. Boixo, P. Bunyk, N. Dickson, C. Enderud, J. P. Hilton, E. Hoskinson, M. W. Johnson, E. Ladizinsky, N. Ladizinsky, R. Neufeld, T. Oh, I. Perminov, C. Rich, M. C. Thom, E. Tolkacheva, S. Uchaikin, A. B. Wilson, and G. Rose

Subjects

Physics, QC1-999

Abstract

Entanglement lies at the core of quantum algorithms designed to solve problems that are intractable by classical approaches. One such algorithm, quantum annealing (QA), provides a promising path to a practical quantum processor. We have built a series of architecturally scalable QA processors consisting of networks of manufactured interacting spins (qubits). Here, we use qubit tunneling spectroscopy to measure the energy eigenspectrum of two- and eight-qubit systems within one such processor, demonstrating quantum coherence in these systems. We present experimental evidence that, during a critical portion of QA, the qubits become entangled and entanglement persists even as these systems reach equilibrium with a thermal environment. Our results provide an encouraging sign that QA is a viable technology for large-scale quantum computing.

Published

2014

2. Tunneling spectroscopy using a probe qubit

Author

Emile Hoskinson, E. Ladizinsky, Paul I. Bunyk, C. Rich, Fabio Altomare, Neil G. Dickson, A. B. Wilson, Mohammad H. Amin, Sergey Uchaikin, A. J. Przybysz, Trevor Lanting, C. Enderud, A. Yu. Smirnov, R. Neufeld, E. Tolkacheva, Richard Harris, Mark W. Johnson, and Andrew J. Berkley

Subjects

Physics, Flux qubit, Quantum Physics, Charge qubit, Condensed matter physics, Condensed Matter - Superconductivity, FOS: Physical sciences, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, law.invention, SQUID, Phase qubit, Superconductivity (cond-mat.supr-con), law, Qubit, Atomic physics, Spectroscopy, Quantum Physics (quant-ph), Quantum tunnelling, Quantum computer

Abstract

We describe a quantum tunneling spectroscopy technique that requires only low-bandwidth control. The method involves coupling a probe qubit to the system under study to create a localized probe state. The energy of the probe state is then scanned with respect to the unperturbed energy levels of the probed system. Incoherent tunneling transitions that flip the state of the probe qubit occur when the energy bias of the probe is close to an eigenenergy of the probed system. Monitoring these transitions allows the reconstruction of the probed system eigenspectrum. We demonstrate this method on an rf SQUID flux qubit.

Published

2012

3. Thermally assisted quantum annealing of a 16-qubit problem.

Author

Dickson NG, Johnson MW, Amin MH, Harris R, Altomare F, Berkley AJ, Bunyk P, Cai J, Chapple EM, Chavez P, Cioata F, Cirip T, Debuen P, Drew-Brook M, Enderud C, Gildert S, Hamze F, Hilton JP, Hoskinson E, Karimi K, Ladizinsky E, Ladizinsky N, Lanting T, Mahon T, Neufeld R, Oh T, Perminov I, Petroff C, Przybysz A, Rich C, Spear P, Tcaciuc A, Thom MC, Tolkacheva E, Uchaikin S, Wang J, Wilson AB, Merali Z, and Rose G

Abstract

Efforts to develop useful quantum computers have been blocked primarily by environmental noise. Quantum annealing is a scheme of quantum computation that is predicted to be more robust against noise, because despite the thermal environment mixing the system's state in the energy basis, the system partially retains coherence in the computational basis, and hence is able to establish well-defined eigenstates. Here we examine the environment's effect on quantum annealing using 16 qubits of a superconducting quantum processor. For a problem instance with an isolated small-gap anticrossing between the lowest two energy levels, we experimentally demonstrate that, even with annealing times eight orders of magnitude longer than the predicted single-qubit decoherence time, the probabilities of performing a successful computation are similar to those expected for a fully coherent system. Moreover, for the problem studied, we show that quantum annealing can take advantage of a thermal environment to achieve a speedup factor of up to 1,000 over a closed system.

Published

2013

4. Quantum annealing with manufactured spins.

Author

Johnson MW, Amin MH, Gildert S, Lanting T, Hamze F, Dickson N, Harris R, Berkley AJ, Johansson J, Bunyk P, Chapple EM, Enderud C, Hilton JP, Karimi K, Ladizinsky E, Ladizinsky N, Oh T, Perminov I, Rich C, Thom MC, Tolkacheva E, Truncik CJ, Uchaikin S, Wang J, Wilson B, and Rose G

Abstract

Many interesting but practically intractable problems can be reduced to that of finding the ground state of a system of interacting spins; however, finding such a ground state remains computationally difficult. It is believed that the ground state of some naturally occurring spin systems can be effectively attained through a process called quantum annealing. If it could be harnessed, quantum annealing might improve on known methods for solving certain types of problem. However, physical investigation of quantum annealing has been largely confined to microscopic spins in condensed-matter systems. Here we use quantum annealing to find the ground state of an artificial Ising spin system comprising an array of eight superconducting flux quantum bits with programmable spin-spin couplings. We observe a clear signature of quantum annealing, distinguishable from classical thermal annealing through the temperature dependence of the time at which the system dynamics freezes. Our implementation can be configured in situ to realize a wide variety of different spin networks, each of which can be monitored as it moves towards a low-energy configuration. This programmable artificial spin network bridges the gap between the theoretical study of ideal isolated spin networks and the experimental investigation of bulk magnetic samples. Moreover, with an increased number of spins, such a system may provide a practical physical means to implement a quantum algorithm, possibly allowing more-effective approaches to solving certain classes of hard combinatorial optimization problems.

Published

2011