Spins in solids or in molecules possess discrete energy levels, and the associated quantum
states can be tuned and coherently manipulated by means of external electromagnetic …

The past few years have witnessed the concrete and fast spreading of quantum
technologies for practical computation and simulation. In particular, quantum computing …

Implementation of modern Quantum Technologies might benefit from the remarkable
quantum properties shown by molecular spin systems. In this Perspective, we highlight the …

Artificial magnetic molecules can contribute to progressing toward large scale quantum
computation by (a) integrating multiple quantum resources and (b) reducing the …

Over recent decades, much effort has been made to lengthen spin relaxation/decoherence
times of single-molecule magnets and molecular qubits by following different chemical …

To design molecular spin qubits and nanomagnets operating at high temperatures, there is
an urgent need to understand the relationship between vibrations and spin relaxation …

We show that molecular nanomagnets have a potential advantage in the crucial rush toward
quantum computers. Indeed, the sizable number of accessible low-energy states of these …

The realization of quantum information processing would disrupt the status quo in the realm
of computation; the extraordinary power of a hypothetical quantum computer motivates …

We show that a [Er–Ce–Er] molecular trinuclear coordination compound is a promising
platform to implement the three-qubit quantum error correction code protecting against pure …

Atomic-scale magnetic moments in contact with superconductors host rich physics based on
the emergence of Yu–Shiba–Rusinov (YSR) magnetic bound states within the …