Abstract
Quantum teleportation exemplifies how the transmission of quantum information starkly differs from that of classical information and serves as a key protocol for quantum communication and quantum computing. While an ideal teleportation protocol requires noiseless quantum channels to share a pure maximally entangled state, the reality is that shared entanglement is often severely degraded due to various decoherence mechanisms. Although the quantum noise induced by the decoherence is indeed a major obstacle to realizing a near-term quantum network or processor with a limited number of qubits, the methodologies considered thus far to address this issue are resource-intensive. Here, we demonstrate a protocol that allows optimal quantum teleportation via noisy quantum channels without additional qubit resources. By analyzing teleportation in the framework of generalized quantum measurement, we optimize the teleportation protocol for noisy quantum channels. In particular, we experimentally demonstrate that our protocol enables to teleport an unknown qubit even via a single copy of an entangled state under strong decoherence that would otherwise preclude any quantum operation. Our work provides a useful methodology for practically coping with decoherence with a limited number of qubits and paves the way for realizing noisy intermediate-scale quantum computing and quantum communication.
Highlights
Quantum teleportation is a process of transmitting an arbitrary unknown quantum state via a quantum and a classical channel[1].The quantum channel is served by an entangled state shared between the sender and receiver
We have proposed and experimentally demonstrated a protocol for optimal quantum teleportation via noisy quantum channels, which does not require any additional qubits
We have shown that quantum teleportation can be generally optimized in the framework of generalized quantum measurements and corresponding reversing operations
Summary
Quantum teleportation is a process of transmitting an arbitrary unknown quantum state via a quantum and a classical channel[1]. The quantum channel is served by an entangled state shared between the sender and receiver This exemplifies how starkly quantum information differs from classical information and provides a fundamental building block for various protocols in both quantum communication[2] and quantum computing[3,4]. Classical post-processing has been used to mitigate the effect of errors in estimating an expectation value without requiring ancillary qubits[31,32,33]; such a technique is not applicable for the transfer of quantum information via a noisy channel. We demonstrate a protocol that allows optimal quantum teleportation via noisy quantum channels without additional qubits. We experimentally demonstrate that our protocol enables quantum teleportation even via highly noisy quantum channels (i.e., an entangled state under strong decoherence) that would otherwise preclude any quantum operations
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