Probing Quantum Telecloning on Superconducting Quantum Processors

TL;DR

This paper demonstrates the implementation of universal quantum telecloning circuits on IBM superconducting quantum processors, achieving high fidelity for small numbers of clones and analyzing the effects of circuit optimization and error suppression techniques.

Contribution

It presents the first experimental realization of $1 ightarrow M$ quantum telecloning circuits on superconducting processors with real-time classical control and comprehensive fidelity analysis.

Findings

Achieved clone fidelity of up to 0.79 for $M=2$ with error suppression.

Demonstrated circuits for $M=2$ to $M=10$ on 7 IBM Quantum processors.

Fidelity decreases to 0.5 for $M > 5$, highlighting limitations in current NISQ devices.

Abstract

Quantum information can not be perfectly cloned, but approximate copies of quantum information can be generated. Quantum telecloning combines approximate quantum cloning, more typically referred as quantum cloning, and quantum teleportation. Quantum telecloning allows approximate copies of quantum information to be constructed by separate parties, using the classical results of a Bell measurement made on a prepared quantum telecloning state. Quantum telecloning can be implemented as a circuit on quantum computers using a classical co-processor to compute classical feed forward instructions using if statements based on the results of a mid-circuit Bell measurement in real time. We present universal, symmetric, optimal $1 \rightarrow M$ telecloning circuits, and experimentally demonstrate these quantum telecloning circuits for $M=2$ up to $M=10$, natively executed with real time classical control systems on IBM Quantum superconducting processors, known as dynamic circuits. We perform the cloning procedure on many different message states across the Bloch sphere, on $7$ IBM Quantum processors, optionally using the error suppression technique X-X sequence digital dynamical decoupling. Two circuit optimizations are utilized, one which removes ancilla qubits for $M=2, 3$, and one which reduces the total number of gates in the circuit but still uses ancilla qubits. Parallel single qubit tomography with MLE density matrix reconstruction is used in order to compute the mixed state density matrices of the clone qubits, and clone quality is measured using quantum fidelity. These results present one of the largest and most comprehensive NISQ computer experimental analyses on (single qubit) quantum telecloning to date. The clone fidelity sharply decreases to $0.5$ for $M > 5$, but for $M=2$ we are able to achieve a mean clone fidelity of up to $0.79$ using dynamical decoupling.