Design and Experimental Realization of Various Protocols for Secure Quantum Computation and Communication

TL;DR

This paper presents new schemes for secure quantum computation and communication, experimentally demonstrating quantum teleportation, broadcasting, operator implementation, and secure multiparty protocols on IBM's quantum computer.

Contribution

It introduces novel protocols for quantum teleportation, broadcasting, operator remote implementation, and secure multiparty tasks, with experimental realizations and performance analysis.

Findings

Demonstrated multi-output quantum teleportation with fewer resources.

Realized quantum broadcasting and remote operator implementation schemes.

Implemented secure quantum voting and analyzed quantum key distribution protocols.

Abstract

A set of new schemes for quantum computation and communication have been either designed or experimentally realized using optimal quantum resources. A multi-output quantum teleportation scheme, where a sender (Alice) teleports an m and m+1-qubit GHZ-like unknown state to a receiver (Bob), has been demonstrated using two copies of the Bell state instead of a five-qubit cluster state and implemented on IBM's quantum computer for the m=1 case. Another scheme, known as quantum broadcasting where a known state is sent to two spatially separated parties (Bob and Charlie) has also been realized using two Bell states. It is shown that existing quantum broadcasting schemes can be reduced to multiparty remote state preparation. After achieving teleportation of unknown and known states, sending a quantum operator becomes the next step. A scheme for remote implementation of operators (RIO), specifically a controlled joint-RIO (CJRIO), has been proposed using a four-qubit hyper-entangled state involving spatial and polarization degrees of freedom. In this direction, two more variants, remote implementation of hidden and partially unknown operators (RIHO and RIPUO) have also been proposed. Their success probabilities are analyzed considering dissipation of an auxiliary coherent state interacting with the environment. For secure multiparty tasks like quantum voting or auction, secure multiparty quantum computation (SMQC) becomes essential. A quantum anonymous voting (QAV) scheme has been experimentally implemented on IBM's quantum computer. Finally, two quantum key distribution (QKD) protocols, coherent one-way (COW) and differential phase shift (DPS), are experimentally demonstrated and the key rates are analyzed as functions of post-processing parameters and detector dead times across various distances.