Exploring the Scalability and Error Tolerance of N-Qubit Superdense Coding

Benjamin Heinz, Illinois Wesleyan University

Major

Physics

Second Major

Music Instrumental Performance

Submission Type

Poster

Area of Study or Work

Physics

Faculty Advisor

Narendra Jaggi

Location

CNS Atrium

Start Date

4-12-2025 11:15 AM

End Date

4-12-2025 12:15 PM

Abstract

Superdense coding is a quantum communication protocol that enables the transmission of more than one classical bit of information per qubit, using entangled states. While superdense coding with 2-qubits is well understood and directly maps to the Bell states, the same cannot be said for higher numbers of qubits. This project aims to develop an algorithm for superdense coding using a larger number of qubits, while analyzing how the capacity for information transmission scales with qubit count. Additionally, we will determine the error thresholds for accurately reconstructing the encoded information and investigate how error scales as the number of qubits increases. Gaining a deeper understanding of superdense coding has significant applications in quantum cryptography, as superdense coding schemes can be used to set up quantum secure direct communication (QSDC) protocols.

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Apr 12th, 11:15 AM Apr 12th, 12:15 PM

Exploring the Scalability and Error Tolerance of N-Qubit Superdense Coding

CNS Atrium

Superdense coding is a quantum communication protocol that enables the transmission of more than one classical bit of information per qubit, using entangled states. While superdense coding with 2-qubits is well understood and directly maps to the Bell states, the same cannot be said for higher numbers of qubits. This project aims to develop an algorithm for superdense coding using a larger number of qubits, while analyzing how the capacity for information transmission scales with qubit count. Additionally, we will determine the error thresholds for accurately reconstructing the encoded information and investigate how error scales as the number of qubits increases. Gaining a deeper understanding of superdense coding has significant applications in quantum cryptography, as superdense coding schemes can be used to set up quantum secure direct communication (QSDC) protocols.