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Quantum-safe hybrid key exchanges with KEM-based authentication.

Christopher Battarbee1, Christoph Striecks2, Ludovic Perret3,1

  • 1Sorbonne University, CNRS, LIP6 F-75005, Paris, France.

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|November 13, 2025
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Summary
This summary is machine-generated.

Muckle# enhances hybrid authenticated key exchange (HAKE) for quantum-safe networks. It uses post-quantum key encapsulation mechanisms (KEMs) for efficient authentication, improving upon Muckle+ protocols.

Keywords:
Hybrid authenticated key exchangePost-quantum cryptographyQuantum cryptography

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Area of Science:

  • Cryptography and Network Security
  • Post-Quantum Cryptography
  • Applied Cryptography

Background:

  • Authenticated Key Exchange (AKE) is crucial for secure digital infrastructures.
  • The Muckle+ protocol offers hybrid AKE for large quantum-safe networks but relies on less efficient post-quantum signatures.
  • Efficiency of post-quantum signatures hinders scalability in large networks.

Purpose of the Study:

  • To propose Muckle#, a novel hybrid AKE protocol for enhanced efficiency in large quantum-safe networks.
  • To address the efficiency limitations of post-quantum signatures in existing HAKE protocols.
  • To explore KEM-based implicit authentication for HAKE, inspired by TLS advancements.

Main Methods:

  • Developed Muckle#, a new HAKE protocol utilizing post-quantum Key Encapsulation Mechanisms (KEMs) for authentication.
  • Adapted KEM-based authentication principles from Transport Layer Security (TLS) protocols like KEMTLS.
  • Introduced novel proof techniques to analyze the security and functionality of the KEM-based approach.
  • Implemented a proof-of-concept to demonstrate the protocol's practicality.

Main Results:

  • Muckle# achieves improved efficiency in hybrid authenticated key exchange by leveraging post-quantum KEMs.
  • The KEM-based authentication results in a modified message flow compared to signature-based methods.
  • A practical proof-of-concept validates the feasibility of Muckle#.

Conclusions:

  • Muckle# presents a more efficient alternative for hybrid authenticated key exchange in large quantum-safe networks.
  • The use of post-quantum KEMs for implicit authentication offers a viable path for scalable HAKE.
  • This work demonstrates the practicality and potential of KEM-based authentication in HAKE protocols.