Chapter 1. Introduction.- Chapter 2. Physics and devices of superconductive electronics.- Chapter 3. Superconductive circuits.- Chapter 4. Rapid single flux quantum (RSFQ) circuits.- Chapter 5. Synchronization.- Chapter 6. Superconductive IC manufacturing.- Chapter 7. EDA for superconductive electronics.- Chapter 8. Compact model of superconductor-ferromagnetic transistor.- Chapter 9. Inductive coupling noise in multilayer superconductive ICs.- Chapter 10. Sense amplifier for spin-based cryogenic memory cell.- Chapter 11. Dynamic single flux quantum majority gates.- Chapter 12. Design guidelines for ERSFQ bias networks.- Chapter 13. Partitioning RSFQ Circuits for Current Recycling.- Chapter 14. GALS clocking and shared interconnect for large scale SFQ systems.- Chapter 15. Design for testability of SFQ circuits.- Chapter 16. Conclusions.

Gleb Krylov graduated from the National Research Nuclear University (Moscow Engineering Physics Institute) in Moscow, Russia, in 2014, with the Specialist degree in computer science and engineering. He received the M.S. and Ph.D. degrees from the University of Rochester in Rochester, New York, both in electrical and computer engineering, in, respectively, 2017 and 2021. He is currently with the Walther Meissner Institute for Low Temperature Research and the Technical University of Munich in Munich, Germany. His research interests include superconductive and cryogenic electronics, quantum computing, and electronic design automation.

Tahereh Jabbari received the B.Sc. and M.Sc. degrees from the Sharif University of Technology, Tehran, Iran in, respectively, 2012 and 2015, and the M.Sc. degree and the Ph.D. degree in, respectively, 2019 and 2023, from the University of Rochester in Rochester, New York, all in electrical engineering. From 2015 to 2017, she was a researcher in the Superconductor Electronics Research Laboratory at Sharif University of Technology. She is currently at National Institute of Standards and Technology in Boulder, Colorado. Her research interests include superconductive integrated circuit fabrication, high Tc superconductive devices, superconductive-ferromagnetic devices, microwave design of superconductive lines, noise models of superconductive circuits, electronic design automation, superconductive and cryogenic electronics, and quantum computing.

High efficiency, large scale, stationary computing systems – supercomputers and data centers – are becoming increasingly important due to the movement of data storage and processing onto remote cloud servers. This book is dedicated to a technology particularly appropriate for this application – superconductive electronics, in particular, rapid single flux quantum circuits. The primary purpose of this book is to introduce and systematize recent developments in superconductive electronics into a cohesive whole to support the further development of large scale computing systems.

• Reviews modern research in the field of superconductive digital electronics, including novel devices and approaches;
• Provides comprehensive background on pertinent topics;
• Describes prospective methodologies for large scale integration of superconductive circuits.