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13 results on '"Kruckenhauser, Andreas"'

1. Dark spin-cats as biased qubits

Author

Kruckenhauser, Andreas, Yuan, Ming, Zheng, Han, Mamaev, Mikhail, Zeng, Pei, Mao, Xuanhui, Xu, Qian, Zache, Torsten V., Jiang, Liang, van Bijnen, Rick, and Zoller, Peter

Subjects
Quantum Physics
Abstract

We present a biased atomic qubit, universally implementable across all atomic platforms, encoded as a `spin-cat' within ground state Zeeman levels. The key characteristic of our configuration is the coupling of the ground state spin manifold of size $F_g \gg 1$ to an excited Zeeman spin manifold of size $F_e = F_g - 1$ using light. This coupling results in eigenstates of the driven atom that include exactly two dark states in the ground state manifold, which are decoupled from light and immune to spontaneous emission from the excited states. These dark states constitute the `spin-cat', leading to the designation `dark spin-cat'. We demonstrate that under strong Rabi drive and for large $F_g$, the `dark spin-cat' is autonomously stabilized against common noise sources and encodes a qubit with significantly biased noise. Specifically, the bit-flip error rate decreases exponentially with $F_g$ relative to the dephasing rate. We provide an analysis of dark spin-cats, their robustness to noise, and discuss bias-preserving single qubit and entangling gates, exemplified on a Rydberg tweezer platform.

Published
2024

2. High-dimensional SO(4)-symmetric Rydberg manifolds for quantum simulation

Author

Kruckenhauser, Andreas, van Bijnen, Rick, Zache, Torsten V., Di Liberto, Marco, and Zoller, Peter

Subjects
Quantum Physics, Condensed Matter - Other Condensed Matter, Condensed Matter - Quantum Gases
Abstract

We develop a toolbox for manipulating arrays of Rydberg atoms prepared in high-dimensional hydrogen-like manifolds in the regime of linear Stark and Zeeman effect. We exploit the SO(4) symmetry to characterize the action of static electric and magnetic fields as well as microwave and optical fields on the well-structured manifolds of states with principal quantum number $n$. This enables us to construct generalized large-spin Heisenberg models for which we develop state-preparation and readout schemes. Due to the available large internal Hilbert space, these models provide a natural framework for the quantum simulation of Quantum Field Theories, which we illustrate for the case of the sine-Gordon and massive Schwinger models. Moreover, these high-dimensional manifolds also offer the opportunity to perform quantum information processing operations for qudit-based quantum computing, which we exemplify with an entangling gate and a state-transfer protocol for the states in the neighborhood of the circular Rydberg level., Comment: 16 + 12 pages, 10 figures

Published
2022

3. Realizing distance-selective interactions in a Rydberg-dressed atom array

Author

Hollerith, Simon, Srakaew, Kritsana, Wei, David, Rubio-Abadal, Antonio, Adler, Daniel, Weckesser, Pascal, Kruckenhauser, Andreas, Walther, Valentin, van Bijnen, Rick, Rui, Jun, Gross, Christian, Bloch, Immanuel, and Zeiher, Johannes

Subjects
Condensed Matter - Quantum Gases, Physics - Atomic Physics, Quantum Physics
Abstract

Measurement-based quantum computing relies on the rapid creation of large-scale entanglement in a register of stable qubits. Atomic arrays are well suited to store quantum information, and entanglement can be created using highly-excited Rydberg states. Typically, isolating pairs during gate operation is difficult because Rydberg interactions feature long tails at large distances. Here, we engineer distance-selective interactions that are strongly peaked in distance through off-resonant laser coupling of molecular potentials between Rydberg atom pairs. Employing quantum gas microscopy, we verify the dressed interactions by observing correlated phase evolution using many-body Ramsey interferometry. We identify atom loss and coupling to continuum modes as a limitation of our present scheme and outline paths to mitigate these effects, paving the way towards the creation of large-scale entanglement., Comment: 5 pages, 4 figures + supplementary information

Published
2021
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4. Topological phonons in arrays of ultracold dipolar particles

Author

Di Liberto, Marco, Kruckenhauser, Andreas, Zoller, Peter, and Baranov, Mikhail A.

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics
Abstract

The notion of topology in physical systems is associated with the existence of a nonlocal ordering that is insensitive to a large class of perturbations. This brings robustness to the behaviour of the system and can serve as a ground for developing new fault-tolerant applications. We discuss how to design and study a large variety of topology-related phenomena for phonon-like collective modes in arrays of ultracold polarized dipolar particles. These modes are coherently propagating vibrational excitations, corresponding to oscillations of particles around their equilibrium positions, which exist in the regime where long-range interactions dominate over single-particle motion. We demonstrate that such systems offer a distinct and versatile tool to investigate a wide range of topological effects in a single experimental setup with a chosen underlying crystal structure by simply controlling the anisotropy of the interactions via the orientation of the external polarizing field. Our results show that arrays of dipolar particles provide a promising unifying platform to investigate topological phenomena with phononic modes., Comment: 21 pages + 9 figures and 1 table

Published
2021
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5. Quantum optimization via four-body Rydberg gates

Author

Dlaska, Clemens, Ender, Kilian, Mbeng, Glen Bigan, Kruckenhauser, Andreas, Lechner, Wolfgang, and van Bijnen, Rick

Subjects
Quantum Physics, Condensed Matter - Quantum Gases
Abstract

There is a large ongoing research effort towards obtaining a quantum advantage in the solution of combinatorial optimization problems on near-term quantum devices. A particularly promising platform for testing and developing quantum optimization algorithms are arrays of trapped neutral atoms, laser-coupled to highly excited Rydberg states. However, encoding combinatorial optimization problems in atomic arrays is challenging due to the limited inter-qubit connectivity given by their native finite-range interactions. Here we propose and analyze a fast, high fidelity four-body Rydberg parity gate, enabling a direct and straightforward implementation of the Lechner-Hauke-Zoller (LHZ) scheme and its recent generalization, the parity architecture, a scalable architecture for encoding arbitrarily connected interaction graphs. Our gate relies on onetime-optimized adiabatic laser pulses and is fully programmable by adjusting two hold-times during operation. We numerically demonstrate an implementation of the quantum approximate optimization algorithm (QAOA) for a small scale test problem. Our approach allows for efficient execution of variational optimization steps with a constant number of system manipulations, independent of the system size, thus paving the way for experimental investigations of QAOA beyond the reach of numerical simulations., Comment: 11 pages

Published
2021
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6. Quantum Many-Body Physics with Ultracold Polar Molecules: Nanostructured Potential Barriers and Interactions

Author

Kruckenhauser, Andreas, Sieberer, Lukas M., Tobias, William G., Matsuda, Kyle, De Marco, Luigi, Li, Jun-Ru, Valtolina, Giacomo, Rey, Ana Maria, Ye, Jun, Baranov, Mikhail A., and Zoller, Peter

Subjects
Condensed Matter - Quantum Gases, Quantum Physics
Abstract

We design dipolar quantum many-body Hamiltonians that will facilitate the realization of exotic quantum phases under current experimental conditions achieved for polar molecules. The main idea is to modulate both single-body potential barriers and two-body dipolar interactions on a spatial scale of tens of nanometers to strongly enhance energy scales and, therefore, relax temperature requirements for observing new quantum phases of engineered many-body systems. We consider and compare two approaches. In the first, nanoscale barriers are generated with standing wave optical light fields exploiting optical nonlinearities. In the second, static electric field gradients in combination with microwave dressing are used to write nanostructured spatial patterns on the induced electric dipole moments, and thus dipolar interactions. We study the formation of inter-layer and interface bound states of molecules in these configurations, and provide detailed estimates for binding energies and expected losses for present experimental setups., Comment: 21 pages, 7 figures

Published
2020
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7. Dynamical Equilibration of Topological Properties

Author

Kruckenhauser, Andreas and Budich, Jan Carl

Subjects
Condensed Matter - Quantum Gases, Quantum Physics
Abstract

We study the dynamical process of equilibration of topological properties in quantum many-body systems undergoing a parameter quench between two topologically inequivalent Hamiltonians. This scenario is motivated by recent experiments on ultracold atomic gases, where a trivial initial state is prepared before the Hamiltonian is ramped into a topological insulator phase. While the many-body wave function must stay topologically trivial in the coherent post-quench dynamics, here we show how the topological properties of the single particle density matrix dynamically change and equilibrate in the presence of interactions. In this process, the single particle density matrix goes through a characteristic level crossing as a function of time, which plays an analogous role to the gap closing of a Hamiltonian in an equilibrium topological quantum phase transition. As an exact case study exemplifying this mechanism, we numerically solve the quench dynamics of an interacting one-dimensional topological insulator.

Published
2017
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11. Realizing Distance-Selective Interactions in a Rydberg-Dressed Atom Array

Author

Hollerith, Simon, primary, Srakaew, Kritsana, additional, Wei, David, additional, Rubio-Abadal, Antonio, additional, Adler, Daniel, additional, Weckesser, Pascal, additional, Kruckenhauser, Andreas, additional, Walther, Valentin, additional, van Bijnen, Rick, additional, Rui, Jun, additional, Gross, Christian, additional, Bloch, Immanuel, additional, and Zeiher, Johannes, additional

Published
2022
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