Your search keyword '"Schmiedmayer, Jorg"' showing total 3 results

1. Ergodic-localized junctions in a periodically-driven spin chain

Author

Zha, Chen, Bastidas, V. M., Gong, Ming, Wu, Yulin, Rong, Hao, Yang, Rui, Ye, Yangsen, Li, Shaowei, Zhu, Qingling, Wang, Shiyu, Zhao, Youwei, Liang, Futian, Lin, Jin, Xu, Yu, Peng, Cheng-Zhi, Schmiedmayer, Jorg, Nemoto, Kae, Deng, Hui, Munro, W. J., Zhu, Xiaobo, and Pan, Jian-Wei

Subjects

Quantum Physics, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons

Abstract

We report the analogue simulation of an ergodiclocalized junction by using an array of 12 coupled superconducting qubits. To perform the simulation, we fabricated a superconducting quantum processor that is divided into two domains: a driven domain representing an ergodic system, while the second is localized under the effect of disorder. Due to the overlap between localized and delocalized states, for small disorder there is a proximity effect and localization is destroyed. To experimentally investigate this, we prepare a microwave excitation in the driven domain and explore how deep it can penetrate the disordered region by probing its dynamics. Furthermore, we performed an ensemble average over 50 realizations of disorder, which clearly shows the proximity effect. Our work opens a new avenue to build quantum simulators of driven-disordered systems with applications in condensed matter physics and material science

Published

2020

2. Current-induced magnetization hysteresis defines atom trapping in a superconducting atomchip

Author

Diorico, Fritz, Minniberger, Stefan, Weigner, Thomas, Gerstenecker, Benedikt, Shokrani, Naz, Kurpias, Zaneta, and Schmiedmayer, Jorg

Subjects

Physics - Atomic Physics

Abstract

The physics of superconducting films, and especially the role of remnant magnetization has a defining influence on the magnetic fields used to hold and manipulate atoms on superconducting atomchips. We magnetically trap ultracold ^{87}Rb atoms on a 200{\mu}m wide and 500nm thick cryogenically cooled niobium Z wire structure. By measuring the distance of the atomcloud to the trapping wire for different transport currents and bias fields, we probe the trapping characteristics of the niobium superconducting structure. At distances closer than the trapping wire width, we observe a different behaviour than that of normal conducting wire traps. Furthermore, we measure a stable magnetic trap at zero transport current. These observations point to the presence of a remnant magnetization in our niobium film which is induced by a transport current. This current-induced magnetization defines the trap close to the chip surface. Our measurements agree very well with an analytic prediction based on the critical state model (CSM). Our results provide a new tool to control atom trapping on superconducting atomchips by designing the current distribution through its current history., Comment: 14pages, 7 figures

Published

2018

3. Photonic architecture for scalable quantum information processing in NV-diamond

Author

Nemoto, Kae, Trupke, Michael, Devitt, Simon J., Stephens, Ashley M., Buczak, Kathrin, Nobauer, Tobias, Everitt, Mark S., Schmiedmayer, Jorg, and Munro, William J.

Subjects

Quantum Physics

Abstract

Physics and information are intimately connected, and the ultimate information processing devices will be those that harness the principles of quantum mechanics. Many physical systems have been identified as candidates for quantum information processing, but none of them are immune from errors. The challenge remains to find a path from the experiments of today to a reliable and scalable quantum computer. Here, we develop an architecture based on a simple module comprising an optical cavity containing a single negatively-charged nitrogen vacancy centre in diamond. Modules are connected by photons propagating in a fiber-optical network and collectively used to generate a topological cluster state, a robust substrate for quantum information processing. In principle, all processes in the architecture can be deterministic, but current limitations lead to processes that are probabilistic but heralded. We find that the architecture enables large-scale quantum information processing with existing technology., Comment: 24 pages, 14 Figures. Comment welcome

Published

2013