Cryogenic CMOS interfaces for large-scale quantum computers: from system & device models to circuits скачать в хорошем качестве

Cryogenic CMOS interfaces for large-scale quantum computers: from system & device models to circuits

Abstract: Quantum computers operate by processing information stored in quantum bits (qubits), which must typically operate at cryogenic temperature. A practical quantum computer will comprise thousands of qubits, thus requiring an electronic interface also operating at cryogenic temperature to ensure integration and scalability of the whole system. Focusing on the use of standard CMOS technology, we will explore the challenges in building such interface, comprising modeling of the quantum/classical interface, devices modeling for cryogenic CMOS and the design of high-performance cryogenic CMOS circuits. By demonstrating the cryogenic operation of complex CMOS analog and digital systems, we will show that cryogenic CMOS is a viable technology to enable large-scale quantum computing. Bio: Fabio Sebastiano holds degrees in Electrical Engineering from University of Pisa, Italy (BSc, 2003; MSc, 2005) from Sant’Anna school of Advanced Studies, Pisa, Italy (MSc, 2006) and from Delft University of Technology, The Netherlands (PhD, 2011). From 2006 to 2013, he was with NXP Semiconductors Research in Eindhoven, The Netherlands. In 2013, he joined Delft University of Technology, where he is currently an Assistant Professor. He has authored or co-authored one book, ten patents, and over 60 technical publications. His main research interests are cryogenic electronics for quantum applications, sensor read-outs and frequency references. Dr. Sebastiano was the co-recipient of the best student paper award at ISCAS in 2008, the best paper award at IWASI in 2017 and the best IP award at DATE in 2018. He is a senior member of IEEE, a TPC member for RFIC and a Distinguished Lecturer of the IEEE Solid-State Circuit Society.