Quantum Key Distribution-based Techniques in IoT
Downloads
Published
DOI:
https://doi.org/10.58414/SCIENTIFICTEMPER.2023.14.3.69Keywords:
Authentication,Cryptography, Internet of Things, Quantum Computing, Quantum Key Distribution.Dimensions Badge
Issue
Section
License
Copyright (c) 2023 The Scientific Temper
This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.
Quantum key distribution (QKD) is a cryptographic technique that creates a secure channel of communication between two parties by applying the ideas of quantum physics. QKD ensures the confidentiality and integrity of data transmission by providing a unique key that the intended recipient can only access. Secure communication has become paramount with the proliferation of IoT (Internet of Things) devices. IoT devices have confined computational power and storage, making them vulnerable to attacks. QKD provides a safe and efficient solution for securing communication between IoT devices. This paper examines how QKD can be utilized in IoT, discussing its benefits and limitations, followed by the discussion on various QKD protocols suitable for IoT devices. In addition, the paper demonstrates that QKD is a promising solution for securing IoT communication, and its adoption significantly enhances the security and reliability of IoT networks.Abstract
How to Cite
Downloads
Similar Articles
- Sheena Edavalath, Manikandasaran S. Sundaram, MARCR: Method of allocating resources based on cost of the resources in a heterogeneous cloud environment , The Scientific Temper: Vol. 14 No. 03 (2023): The Scientific Temper
- S. Manohar, T. P. Vijayakumar, Optimization of gluten-free bread using RSM (Design Expert) to study its textural and sensory properties , The Scientific Temper: Vol. 14 No. 04 (2023): The Scientific Temper
- Ahmed Mustefa, Ethiopian Voluntary Resettlement Programme-Lesson to Learn , The Scientific Temper: Vol. 14 No. 01 (2023): The Scientific Temper
- R. Gomathi, Balaji V, Sanjay R. Pawar, Ayesha Siddiqua, M. Dhanalakshmi, Ravi Rastogi, Ensuring ethical integrity and bias reduction in machine learning models , The Scientific Temper: Vol. 15 No. 01 (2024): The Scientific Temper
- Olivia C. Gold, Jayasimman Lawrence, Ensemble of CatBoost and neural networks with hybrid feature selection for enhanced heart disease prediction , The Scientific Temper: Vol. 15 No. 04 (2024): The Scientific Temper
- P. Pattunnarajam, Janani G, A. Vijayaraj, Sathiya Priya S, Enhanced routing strategy of wireless sensor network based on fifth generation communication technology , The Scientific Temper: Vol. 14 No. 04 (2023): The Scientific Temper
- A. Anand, A. Nisha Jebaseeli, AI-driven real-time performance optimization and comparison of virtual machines and containers in cloud environments , The Scientific Temper: Vol. 15 No. spl-1 (2024): The Scientific Temper
- Brigith Gladys L, Merline Vinotha J, Sustainable fuzzy rough multi-objective multi-route cold transportation model with traffic flow and route constraints , The Scientific Temper: Vol. 16 No. 01 (2025): The Scientific Temper
- S. Kumar, M. Santhanalakshmi , R. Navaneethakrishnan, Content addressable memory for energy efficient computing applications , The Scientific Temper: Vol. 14 No. 02 (2023): The Scientific Temper
- Brigith Gladys L, J. Merline Vinotha, Sustainable rough multi-objective two-stage solid transportation problem of third-party e-commerce logistic providers with conditional fixed parameter on safety , The Scientific Temper: Vol. 16 No. 01 (2025): The Scientific Temper
<< < 7 8 9 10 11 12 13 14 15 16 > >>
You may also start an advanced similarity search for this article.
