10 best quantum cryptography books of all time

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by Madhurjya Chowdhury


October 5, 2021

Quantum cryptography is a branch of research that uses the principles of quantum mechanics to encrypt and transmit data, making it impossible for hackers, even those with quantum computing capabilities, to access it. The development and execution of different cryptographic tasks using the advanced skills and power of quantum computers are also included in the wider use of quantum cryptography. Quantum computers have the potential to help create new, stronger and more precise encryption methods that would be difficult to create with today’s computing and communications infrastructures.

Here are the 10 best quantum cryptography books you can read to learn more about the concept.

# 1. Generation of quantum random numbers

This book provides an overview of current solutions of the Quantum Random Number Generator (QRNG), emphasizing their relationship to classical concepts of statistical randomness and numerical methods of calculating random numbers. The reader, who should preferably have a background in probability and statistics, computer programming or cryptography, will be guided step by step in the field of quantum bits, with clear relationships between QRNGs and their classical equivalents established along the line. line.

# 2. The 2020-2025 Global Outlook for Quantum Cryptography

This report examines the global outlook for quantum cryptography in more than 190 countries. The latent market figures, or Industry Potential Gains (PIEs), for the country in question (in millions of US dollars), as well as the country’s market share as a percentage of the area and the world, are given for each year presented. These benchmarks allow the reader to quickly assess the position of a country in relation to others. Estimates of implicit demand are calculated using econometric models that project basic economic processes within and between countries.

This study does not go into detail on the individual market players who meet latent demand, nor on the specifics of specific products.

# 3. Quantum cryptography

The United States Air Force is expected to learn more about quantum physics and its application to encryption, according to this research. Quantum encryption is inevitable, according to a study of scientists and academic organizations undertaking research to better understand and use quantum cryptography. The attempt to learn and use this information must be made with the full understanding that quantum cryptography is not a split down the road that requires a choice, but rather a technical necessity.

# 4. Applied quantum cryptography

This is a brand new technology that uses the quantum characteristics of single photons to transfer binary keys between two parties for future encryption of secret data. A few years ago, quantum cryptography, or more precisely the distribution of quantum keys, was the domain of university basic research facilities. However, things have changed in recent years. Quantum Key Distribution, or QKD, left the lab and was picked up by more pragmatic teams who worked hard to create viable technology from the amazing discoveries of basic research.

# 5. Quantum computing for high school students

Peter Shor devised a quantum algorithm in 1994 that, once large-scale quantum computers were built, would break much of the cryptography used in digital communications. Quantum computers are devices that use quantum systems as processors and operate on the principles of quantum mechanics. This book only uses college algebra and trigonometry to explore the fascinating subject of quantum computing. The basis of quantum computing theory is based on concepts from quantum physics, mathematics, computing, and cryptography. One of the goals of this book is to understand Shor’s algorithm.

# 6. Post-quantum cryptography

This book contains the refereed results of the 8th International Workshop on Post-Quantum Cryptography, PQCrypto 2017, which took place in June 2017 in Utrecht, the Netherlands. Out of a total of 67 submissions, the 23 complete revised papers delivered were carefully assessed and selected. Code-based cryptography, quantum algorithms, network-based cryptography, isogeny-based cryptography, multivariate cryptography, and security models are among the topics covered in the articles.

# 7. Introduction to quantum information science

The fundamentals of quantum theory, quantum entanglement, quantum algorithms, quantum entropies, quantum error correction, quantum coding, and quantum cryptography are all covered in this book. The only prerequisites are a basic understanding of calculus and linear algebra. Undergraduates will be able to understand the text this way. To understand quantum information, one must first learn the basics of quantum theory. This book presents it from a more operational point of view, which is appropriate for quantum information, but not standard quantum theory textbooks.

# 8. A New Mechanism to Boost Security in Quantum Cryptography

Today, the main issue is security. Quantum cryptography is a data transfer technology that uses polarization. The study described here proposes a technique that improves the security of data when it is sent. The BB84 protocol serves as the basis for this mechanism. From sender to receiver and from receiver to sender, this protocol is used. The key you get after using the method is pretty safe.

# 9. Physical layer security and quantum key distribution

To meet the highest security controls, this manual incorporates the most advanced topics of physical layer security, covert / stealth communications, cryptography, quantum key distribution (QKD), and cybersecurity. After presenting several concepts and practices to the reader, the author explains how they can be used together to solve problems rather than being treated as separate disciplines.

#ten. Nonlinear laser dynamics

The nonlinear dynamic observations of semiconductor lasers are discussed in a unique way. The book integrates current findings in quantum dot laser modeling with mathematical details and analytical knowledge of nonlinear processes in semiconductor lasers, as well as potential laser applications in encryption and chaos management. This multidisciplinary approach sets it apart as a unique and valuable source of information for anyone interested in contributing to this field of study.

Conclusion

Quantum computers are developing rapidly, promising to provide strong computer skills capable of handling a wide range of crucial, even life-threatening computing problems that ordinary computers cannot. Unfortunately, quantum computers have the potential to generate new dangers at unprecedented speed and scale. Complex mathematical calculations, for example, that take months or years for normal computers to solve can be solved in seconds by quantum computers using quantum algorithms such as Shor’s algorithm. However, systems capable of deciphering classical math-based encryption methods are expected to appear within the next 5-10 years.

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