Bosonic quantum error correction with microwave cavities for quantum repeaters
- URL: http://arxiv.org/abs/2503.21569v1
- Date: Thu, 27 Mar 2025 14:50:57 GMT
- Title: Bosonic quantum error correction with microwave cavities for quantum repeaters
- Authors: S. Siddardha Chelluri, Sanchar Sharma, Frank Schmidt, Silvia Viola Kusminskiy, Peter van Loock,
- Abstract summary: We provide a theoretical analysis of the secret key rates for a quantum repeater system incorporating bosonic error correction and memory components.<n>We discuss a physical implementation of such a quantum repeater comprising a microwave cavity and a superconducting transmon.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Long-distance quantum communication necessitates the use of quantum repeaters, which typically include highly coherent quantum memories. We provide a theoretical analysis of the secret key rates for a quantum repeater system incorporating bosonic error correction and memory components. Specifically, we focus on the application of Binomial codes for two repeater segments. Using these codes, our investigation aims to suppress memory loss errors that commonly affect systems such as atoms and microwave cavities, in contrast to dephasing errors in single-spin memories. We further discuss a physical implementation of such a quantum repeater comprising a microwave cavity and a superconducting transmon, capable of state engineering with high fidelities ($>97\%$) and logical Bell state measurements for successful entanglement swapping. As an alternative approach, we also discuss a realization in the all-optical domain.
Related papers
- Realizing fracton order from long-range quantum entanglement in programmable Rydberg atom arrays [45.19832622389592]
Storing quantum information requires battling quantum decoherence, which results in a loss of information over time.
To achieve error-resistant quantum memory, one would like to store the information in a quantum superposition of degenerate states engineered in such a way that local sources of noise cannot change one state into another.
We show that this platform also allows to detect and correct certain types of errors en route to the goal of true error-resistant quantum memory.
arXiv Detail & Related papers (2024-07-08T12:46:08Z) - Quantum repeaters based on stationary Gottesman-Kitaev-Preskill qubits [0.0]
We consider the bosonic Gottesman-Kitaev-Preskill (GKP) code as a natural choice for a loss-correction-based quantum repeater.
We analyze and assess the performance of such a GKP-based quantum repeater where, apart from the initial state generations and distributions, all operations can be performed via deterministic linear mode transformations.
arXiv Detail & Related papers (2024-06-11T11:04:49Z) - Harnessing Coding Theory for Reliable Network Quantum Communication [7.469588051458094]
We review repeater-based quantum networks, emphasizing the roles of coding theory and fault-tolerant quantum operations.
We highlight that fault-tolerant implementation of the Bell measurement enables reliable quantum communication without requiring a universal set of quantum gates.
arXiv Detail & Related papers (2024-02-29T17:32:08Z) - Quantum error mitigation for Fourier moment computation [49.1574468325115]
This paper focuses on the computation of Fourier moments within the context of a nuclear effective field theory on superconducting quantum hardware.
The study integrates echo verification and noise renormalization into Hadamard tests using control reversal gates.
The analysis, conducted using noise models, reveals a significant reduction in noise strength by two orders of magnitude.
arXiv Detail & Related papers (2024-01-23T19:10:24Z) - Quantum process tomography of continuous-variable gates using coherent
states [49.299443295581064]
We demonstrate the use of coherent-state quantum process tomography (csQPT) for a bosonic-mode superconducting circuit.
We show results for this method by characterizing a logical quantum gate constructed using displacement and SNAP operations on an encoded qubit.
arXiv Detail & Related papers (2023-03-02T18:08:08Z) - Deep Quantum Error Correction [73.54643419792453]
Quantum error correction codes (QECC) are a key component for realizing the potential of quantum computing.
In this work, we efficiently train novel emphend-to-end deep quantum error decoders.
The proposed method demonstrates the power of neural decoders for QECC by achieving state-of-the-art accuracy.
arXiv Detail & Related papers (2023-01-27T08:16:26Z) - Hardware-Efficient, Fault-Tolerant Quantum Computation with Rydberg
Atoms [55.41644538483948]
We provide the first complete characterization of sources of error in a neutral-atom quantum computer.
We develop a novel and distinctly efficient method to address the most important errors associated with the decay of atomic qubits to states outside of the computational subspace.
Our protocols can be implemented in the near-term using state-of-the-art neutral atom platforms with qubits encoded in both alkali and alkaline-earth atoms.
arXiv Detail & Related papers (2021-05-27T23:29:53Z) - Demonstration of quantum advantage by a joint detection receiver for
optical communications using quantum belief propagation on a trapped-ion
device [0.7758302353877525]
We present an experimental realization of a quantum joint detection receiver for binary phase shift keying codewords of a 3-bit linear tree code.
The receiver, translated to a quantum circuit, was experimentally implemented on a trapped-ion device.
We provide an experimental framework that surpasses the quantum limit on the minimum average decoding error probability.
arXiv Detail & Related papers (2021-02-25T18:05:31Z) - Universal quantum computation and quantum error correction with
ultracold atomic mixtures [47.187609203210705]
We propose a mixture of two ultracold atomic species as a platform for universal quantum computation with long-range entangling gates.
One atomic species realizes localized collective spins of tunable length, which form the fundamental unit of information.
We discuss a finite-dimensional version of the Gottesman-Kitaev-Preskill code to protect quantum information encoded in the collective spins.
arXiv Detail & Related papers (2020-10-29T20:17:14Z) - Fault-tolerant Coding for Quantum Communication [71.206200318454]
encode and decode circuits to reliably send messages over many uses of a noisy channel.
For every quantum channel $T$ and every $eps>0$ there exists a threshold $p(epsilon,T)$ for the gate error probability below which rates larger than $C-epsilon$ are fault-tolerantly achievable.
Our results are relevant in communication over large distances, and also on-chip, where distant parts of a quantum computer might need to communicate under higher levels of noise.
arXiv Detail & Related papers (2020-09-15T15:10:50Z) - Testing a Quantum Error-Correcting Code on Various Platforms [5.0745290104790035]
We propose a simple quantum error-correcting code for the detected amplitude damping channel.
We implement the encoding, the channel, and the recovery on an optical platform, the IBM Q System, and a nuclear magnetic resonance system.
arXiv Detail & Related papers (2020-01-22T13:15:16Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.