Machine learning in quantum computing and communication provides intensive
opportunities for revolutionizing the field of Physics, Mathematics, and Computer Science …

We propose a fault-tolerant quantum error correction architecture consisting of a linear array
of emitters and delay lines. In our scheme, a resource state for fault-tolerant quantum …

Real photonic devices are subject to photon losses that can decohere quantum information
encoded in the system. In the absence of full fault tolerance, quantum error mitigation …

Quantum neural networks (QNNs) leverage the strengths of both quantum computing and
neural networks, offering solutions to challenges that are often beyond the reach of …

Quantum error correcting codes typically do not account for quantum state transitions-
leakage-out of the computational subspace. Since these errors can last for multiple detection …

The robustness of quantum memory against physical noises is measured by two methods:
the exact and approximate quantum error correction (QEC) conditions for error …

A quantum error mitigation technique based on machine learning is proposed, which learns
how to adjust the probabilities estimated by measurement in the computational basis. Neural …

Near-term quantum communication protocols suffer inevitably from channel noises, whose
alleviation has been mostly attempted with resources such as multiparty entanglement or …

Accurate decoding of quantum error-correcting codes is a crucial ingredient in protecting
quantum information from decoherence. It requires characterizing the error channels …

Quantum error correcting codes (QECCs) are the means of choice whenever quantum
systems suffer errors, eg, due to imperfect devices, environments, or faulty channels. By …