Microwave Experiments Simulating Quantum Search and Directed Transport in Artificial Graphene

Julian Böhm, Matthieu Bellec, Fabrice Mortessagne, Ulrich Kuhl, Sonja Barkhofen, Stefan Gehler, Hans-Jürgen Stöckmann, Iain Foulger, Sven Gnutzmann, and Gregor Tanner

Phys. Rev. Lett. 114, 110501 – Published 17 March 2015

Abstract

A series of quantum search algorithms have been proposed recently providing an algebraic speedup compared to classical search algorithms from $N$ to $\sqrt{N}$ , where $N$ is the number of items in the search space. In particular, devising searches on regular lattices has become popular in extending Grover’s original algorithm to spatial searching. Working in a tight-binding setup, it could be demonstrated, theoretically, that a search is possible in the physically relevant dimensions 2 and 3 if the lattice spectrum possesses Dirac points. We present here a proof of principle experiment implementing wave search algorithms and directed wave transport in a graphene lattice arrangement. The idea is based on bringing localized search states into resonance with an extended lattice state in an energy region of low spectral density—namely, at or near the Dirac point. The experiment is implemented using classical waves in a microwave setup containing weakly coupled dielectric resonators placed in a honeycomb arrangement, i.e., artificial graphene. Furthermore, we investigate the scaling behavior experimentally using linear chains.

Received 8 September 2014

DOI:https://doi.org/10.1103/PhysRevLett.114.110501

Authors & Affiliations

Julian Böhm¹, Matthieu Bellec¹, Fabrice Mortessagne¹, Ulrich Kuhl^1,*, Sonja Barkhofen^2,3, Stefan Gehler^2,4, Hans-Jürgen Stöckmann², Iain Foulger⁵, Sven Gnutzmann⁵, and Gregor Tanner⁵

¹Laboratoire de Physique de la Matière Condensée, UMR 7336, Université Nice Sophia Antipolis, CNRS, Parc Valrose, 06100 Nice, France
²AG Quantenchaos, Fachbereich Physik der Philipps-Universität Marburg, D-35032 Marburg, Germany
³Applied Physics, University of Paderborn, Warburger Strasse 100, 33098 Paderborn, Germany
⁴Department of Energy Management and Power System Operation, University of Kassel, D-34121 Kassel, Germany
⁵School of Mathematical Sciences, University of Nottingham, University Park, Nottingham NG7 2RD, United Kingdom

^*ulrich.kuhl@unice.fr

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Issue

Vol. 114, Iss. 11 — 20 March 2015

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Images

Figure 1
(Inset) A photograph of the artificial graphene flake, including the supporting metallic plate and the perturber resonators at the boundary (white arrows). The graph shows the DOS of the unperturbed flake (for details, see Ref. [26]), i.e., without a single resonator and dimer attached. The resonance frequencies of the single resonator $ν_{sr}$ and the dimer $ν_{dim}$ are marked by the dashed vertical lines.
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Figure 2
(a) and (c): The initial lattice state at $t = 0$ for two different initial frequency ranges is shown (a) for the range around the lower lattice state $ν_{l}$ including the dimer frequency $ν_{dim}$ and (c) the range around $ν_{s}$ including $ν_{u}$ . (b) and (d): The illuminated perturber state at the search time $t = T_{dim}$ and $T_{s}$ , respectively. The resonators are indicated by the black circles and the color code corresponds to the intensity $P (r, t)$ (dark red: high probability and white: low probability). The color code is rescaled to the maximal value. See the Supplemental Material [38] for a video showing the full dynamics.
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Figure 3
Intensity propagation in an artificial graphene flake with two equal perturbing resonators attached. The initial state at $t = 0$ (a) is localized at the upper resonator and is transferred via a lattice state (b) to the state sitting on the opposite resonator (c). The presentation is as in Fig. 2. See the Supplemental Material [38] for a video showing the full dynamics.
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Figure 4
(a) Experimental setup of the linear chain with $N = 11$ (without a perturber). The top plate and antenna are not shown. The wave function corresponding to the central resonance is superimposed. (b) Reflection measurement of a single resonator (red line, bottom), a regular chain with 11 resonators (black line, center), and a single resonator attached to the chain (blue line, top). The dotted lines mark the frequency range used for the Fourier transform (baselines shifted).
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Figure 5
(a) The intensity $P (r, t)$ of the chain integrated over the 11 resonators (black line) and of the perturber (red line) is shown. The signals are normalized such that the initial state in the chain at $t = 0$ is 1. The corresponding intensity distributions for specific times are shown as insets. See the Supplemental Material [38] for a video showing the full dynamics. (b) The beating time as a function of $N^{'}$ ; solid (red) line: square root dependance; dashed (blue) line: linear increase. The error bars indicate the time difference between different recurrences.
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