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Kangyi Feng1, Yijun Wang1, Yin Li1

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Summary
This summary is machine-generated.

This study introduces wavelength attack schemes for underwater quantum key distribution, enabling eavesdroppers to steal more secret keys by manipulating beam splitters. The attack exploits wavelength-dependent properties in blue-green bands for enhanced security breaches.

Keywords:
continuous-variable quantum key distributiondiscrete modulatedunderwaterwavelength attack

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Area of Science:

  • Quantum Information Science
  • Optical Communication Security
  • Underwater Networks

Background:

  • Continuous-variable quantum key distribution (CV-QKD) is crucial for secure communication.
  • Wavelength attacks exploit beam splitter wavelength dependence to compromise CV-QKD.
  • Underwater channels are vital for secure communication but less explored for QKD security.

Purpose of the Study:

  • To propose and analyze wavelength attack schemes for discrete-modulated (DM) CV-QKD in underwater turbulent channels.
  • To investigate the effectiveness of these attacks with and without a local oscillator (LO) intensity monitor.
  • To determine the conditions under which an eavesdropper can maximize key theft.

Main Methods:

  • Developed two novel wavelength attack schemes tailored for underwater DM-CV-QKD.
  • Utilized the wavelength-dependent transmittance properties of fused biconical taper (FBT) beam splitters.
  • Determined specific blue-green wavelengths for Eve's pulse manipulation.
  • Derived a successful criterion for the attack based on channel transmittance and estimated excess noise.

Main Results:

  • Both proposed wavelength attack schemes effectively reduce the estimated excess noise for Alice and Bob towards zero.
  • The attack's success is contingent on selecting appropriate condition parameters based on channel transmittance.
  • Numerical analysis confirms that minimizing estimated excess noise allows Eve to steal a greater number of secret keys.

Conclusions:

  • Wavelength attacks pose a significant threat to underwater discrete-modulated CV-QKD systems.
  • The proposed schemes are effective in both scenarios with and without an LO intensity monitor.
  • Secure underwater quantum communication requires countermeasures against such wavelength-dependent exploits.