Your search keyword '"Liegener, Klaus"' showing total 3 results

1. Protected Fluxonium Control with Sub-harmonic Parametric Driving

Author

Schirk, Johannes, Wallner, Florian, Huang, Longxiang, Tsitsilin, Ivan, Bruckmoser, Niklas, Koch, Leon, Bunch, David, Glaser, Niklas J., Huber, Gerhard B. P., Knudsen, Martin, Krylov, Gleb, Marx, Achim, Pfeiffer, Frederik, Richard, Lea, Roy, Federico A., Romeiro, João H., Singh, Malay, Södergren, Lasse, Dionis, Etienne, Sugny, Dominique, Werninghaus, Max, Liegener, Klaus, Schneider, Christian M. F., and Filipp, Stefan

Subjects

Quantum Physics

Abstract

Protecting qubits from environmental noise while maintaining strong coupling for fast high-fidelity control is a central challenge for quantum information processing. Here, we demonstrate a novel control scheme for superconducting fluxonium qubits that eliminates qubit decay through the control channel by reducing the environmental density of states at the transition frequency. Adding a low-pass filter on the flux line allows for flux-biasing and at the same time coherently controlling the fluxonium qubit by parametrically driving it at integer fractions of its transition frequency. We compare the filtered to the unfiltered configuration and find a five times longer $T_1$, and ten times improved $T_2$-echo time in the protected case. We demonstrate coherent control with up to 11-photon sub-harmonic drives, highlighting the strong non-linearity of the fluxonium potential. We experimentally determine Rabi frequencies and drive-induced frequency shifts in excellent agreement with numerical and analytical calculations. Furthermore, we show the equivalence of a 3-photon sub-harmonic drive to an on-resonance drive by benchmarking sub-harmonic gate fidelities above 99.94 %. These results open up a scalable path for full qubit control via a single protected channel, strongly suppressing qubit decoherence caused by control lines., Comment: 18 pages, 9 figures

Published

2024

2. Parity-dependent state transfer for direct entanglement generation

Author

Roy, Federico A., Romeiro, João H., Koch, Leon, Tsitsilin, Ivan, Schirk, Johannes, Glaser, Niklas J., Bruckmoser, Niklas, Singh, Malay, Haslbeck, Franz X., Huber, Gerhard B. P., Krylov, Gleb, Marx, Achim, Pfeiffer, Frederik, Schneider, Christian M. F., Schweizer, Christian, Wallner, Florian, Bunch, David, Richard, Lea, Södergren, Lasse, Liegener, Klaus, Werninghaus, Max, and Filipp, Stefan

Subjects

Quantum Physics

Abstract

As quantum information technologies advance they face challenges in scaling and connectivity. In particular, two necessities remain independent of the technological implementation: the need for connectivity between distant qubits and the need for efficient generation of entanglement. Perfect State Transfer is a technique which realises the time optimal transfer of a quantum state between distant nodes of qubit lattices with only nearest-neighbour couplings, hence providing an important tool to improve device connectivity. Crucially, the transfer protocol results in effective parity-dependent non-local interactions, extending its utility to the efficient generation of entangled states. Here, we experimentally demonstrate Perfect State Transfer and the generation of multi-qubit entanglement on a chain of superconducting qubits. The system consists of six fixed-frequency transmon qubits connected by tunable couplers, where the couplings are controlled via parametric drives. By simultaneously activating all couplings and engineering their individual amplitudes and frequencies, we implement Perfect State Transfer on up to six qubits and observe the respective single-excitation dynamics for different initial states. We then apply the protocol in the presence of multiple excitations and verify its parity-dependent property, where the number of excitations within the chain controls the phase of the transferred state. Finally, we utilise this property to prepare a multi-qubit Greenberger-Horne-Zeilinger state using only a single transfer operation, demonstrating its application for efficient entanglement generation., Comment: 16 pages, 10 figures

Published

2024

3. Solving quantum chemistry problems on quantum computers.

Author

Liegener, Klaus, Morsch, Oliver, and Pupillo, Guido

Subjects

*QUANTUM chemistry, *CHEMICAL reactions

Abstract

One of the earliest applications that the new era of computing may be used for is the simulation of the quantum effects that drive chemical reactions. [ABSTRACT FROM AUTHOR]

Published

2024