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Cogent Engineering

For a Special Issue on

Integrated Optical Devices in Quantum Computing and Quantum Communication for Advanced Under Water Optical Communication

Manuscript deadline
30 December 2024

Cover image - Cogent Engineering

Special Issue Editor(s)

Dr. Habib Hamam, University of Moncton, Canada.
[email protected]

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Integrated Optical Devices in Quantum Computing and Quantum Communication for Advanced Under Water Optical Communication

Integrated optical devices play a crucial role in the realm of quantum computing and quantum communication, especially when applied to the domain of advanced underwater optical communication. These devices leverage the principles of quantum mechanics to manipulate and process information in ways that classical systems cannot achieve. In the context of underwater communication, where conventional methods face challenges such as signal degradation and limited bandwidth, integrated optical devices offer innovative solutions. Quantum entanglement, superposition, and other quantum phenomena enable the creation of secure and efficient communication channels. Additionally, integrated optics facilitate the miniaturization of components, essential for underwater applications where space is limited. Through the integration of quantum technologies and optical devices, underwater communication systems can achieve unprecedented levels of data security, speed, and reliability, ushering in a new era of advanced and resilient communication beneath the ocean's surface.

Integrated optical devices face challenges in underwater quantum communication, grappling with signal degradation caused by factors like absorption and scattering. Limited bandwidth underwater complicates the high-data-transfer demands of quantum communication systems. Environmental conditions, such as temperature variations and pressure fluctuations, require stability in integrated devices. Power consumption becomes critical in the underwater environment with potential stringent constraints. Achieving the necessary miniaturization for limited space underwater adds complexity to the design of integrated optical components. Potential topics included, but not limited to:

  • ┬áNovel integrated optical device designs for underwater quantum communication
  • Integrated optical devices in quantum key distribution for underwater environments
  • Integrated optical devices in adaptive signal processing for underwater quantum communication
  • Integrated optical devices in quantum repeaters for underwater quantum networks
  • Power efficient integrated devices for underwater quantum systems
  • Advanced optical materials in materials innovation for under water quantum communication
  • Integrated optical devices in quantum information processing for resource constrained under water environments
  • Integrated optics in quantum key distribution for space to underwater quantum communication
  • Quantum dots in underwater quasi wireless optical communication for underwater environments
  • Integrated optical devices in optical acoustic cooperative communication system for underwater environments