The continuous search for computing-power and data-storage is quickly approaching the physical limits of conventional silicon-based electronics. To overcome these limits, different approaches beyond conventional CMOS technology are presently under investigation. On one hand, quantum computers, based on non-classical superposition of logic units (bit), offer bright perspectives. On the other hand, energy-efficient superconducting circuits based on Josephson junctions have already demonstrated a computational speed 500 times larger than conventional CMOS-based ones. The complete implementation of a supercomputer based on this technology is limited by the lack of memories operating at cryogenic temperatures.
In this context, EuSuper aims at developing a new generation of nano-sized superconducting non-volatile magnetic memories, with improved efficiency and enhanced functionalities. This is accomplished by : 1) exploiting a wise hybridization between ferromagnetic insulators (FI) and conventional superconducting (S) metals; 2) controlling/tuning the superconducting condensate by an external electrostatic field.
The peculiar behavior of FI/S systems is determined by interfacial quantum phenomena arising at the boundary between the ferromagnetic and superconducting materials. Within a distance from the interface of the order of the superconducting coherence length, the exchange interaction of the FI induces a spin split of the density of states into the S, as per an effective Zeeman splitting generated by an external magnetic field of up to few Tesla (magnetic proximity effect). Besides, the recently demonstrated gate-induced tuning of the superconducting order parameter of fully metallic superconductors may play a key role and introduce new paradigms that ultimately add novel unconventional functionalities and physical insights to S and FI-based nanodevices.
The achievements of this project pave the way for innovative superconducting spintronic applications, i.e. in classical large-scale supercomputing, suitable in all fields of science (solid state physics, artificial intelligence, cryptography, etc.) where increasing speed of calculation and storage are exponentially increasing on demand. Also, from a fundamental physics point of view, the results obtained within the project help in clarifying the interplay between the electrostatic fields and the superconducting condensate as well as the ferromagnetism and superconductivity in FI/S mesoscopic devices and spin-valve. From the technological side, EuSuper counts on small size and scalability of systems to develop an innovative class of superconducting memories ready for the market of incoming next-generation cryogenics supercomputers.
EuSuper is a synergic MSCA that combines the capabilities and expertise of two of the most outstanding and globally recognized research institutions: Massachusetts Institute of Technology (USA) and Consiglio Nazionale delle Ricerche (Italy).