Classical cryptography systems exhibit major vulnerabilities because of the rapid development of quan tum computing algorithms and devices. These vulnerabilities were mitigated utilizing quantum key distribution (QKD), which is based on a quantum no-cloning algorithm that assures the safe generation and transmission of the encryption keys. A quantum computing platform, named Qiskit, was utilized by many recent researchers to analyze the security of several QKD protocols, such as BB84 and B92. In this paper, we demonstrate the simulation and implementation of a modified multistage QKD protocol by Qiskit. The simulation and implementation studies were based on the “local_qasm” simulator and the “FakeVigo” backend, respectively. The suggested multistage QKD applies different random commutative sets of Euler’s angles to the transmitted qubits. If Eve successfully hacked the Euler’s angles of a transmitted qubit, Bob will predict the hacking event because other bits apply different Euler’s angles. The commutative sets of Euler’s angles should be selected by a prior agreement between Alice and Bob. Our approach provides additional security proof for the multistage QKD protocol enabling safe public sharing of a sifted key between the sender and receiver
