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Autori principali: 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, Filipp, Stefan
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2405.19408
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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
Filipp, Stefan
author_facet 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
Filipp, Stefan
contents As quantum information technologies advance, challenges in scaling and connectivity persist, particularly the need for long-range qubit connectivity and efficient entanglement generation. Perfect State Transfer enables time-optimal state transfer between distant qubits using only nearest-neighbor couplings, enhancing device connectivity. Moreover, the transfer protocol results in effective parity-dependent non-local interactions, extending its utility to entanglement generation. Here, we experimentally demonstrate Perfect State Transfer and multi-qubit entanglement generation on a chain of six superconducting transmon qubits with tunable couplers, controlled via parametric drives. By simultaneously activating and engineering all couplings, we implement the transfer for up to six qubits, verifying single-excitation dynamics for different initial states. Extending the protocol to multiple excitations, we confirm its parity-dependent nature, where excitation number controls the phase of the transferred state. Finally, leveraging this property, we prepare a Greenberger-Horne-Zeilinger state using a single transfer operation, showcasing the potential of Perfect State Transfer for efficient entanglement generation.
format Preprint
id arxiv_https___arxiv_org_abs_2405_19408
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Parity-dependent state transfer for direct entanglement generation
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
Filipp, Stefan
Quantum Physics
As quantum information technologies advance, challenges in scaling and connectivity persist, particularly the need for long-range qubit connectivity and efficient entanglement generation. Perfect State Transfer enables time-optimal state transfer between distant qubits using only nearest-neighbor couplings, enhancing device connectivity. Moreover, the transfer protocol results in effective parity-dependent non-local interactions, extending its utility to entanglement generation. Here, we experimentally demonstrate Perfect State Transfer and multi-qubit entanglement generation on a chain of six superconducting transmon qubits with tunable couplers, controlled via parametric drives. By simultaneously activating and engineering all couplings, we implement the transfer for up to six qubits, verifying single-excitation dynamics for different initial states. Extending the protocol to multiple excitations, we confirm its parity-dependent nature, where excitation number controls the phase of the transferred state. Finally, leveraging this property, we prepare a Greenberger-Horne-Zeilinger state using a single transfer operation, showcasing the potential of Perfect State Transfer for efficient entanglement generation.
title Parity-dependent state transfer for direct entanglement generation
topic Quantum Physics
url https://arxiv.org/abs/2405.19408