Quantum technologies promise to transform computing and information processing, but their development depends on finding reliable building blocks — known as quantum bits, or qubits. Molecular spin systems are promising qubit candidates because they can be chemically engineered with precision and produced in large numbers. However, a key challenge is understanding how these molecular spins behave when exposed to strong magnetic fields, particularly fields that are highly localized at the nanometer scale.
The OPTIMISTIC project aimed to address this challenge by placing molecular spin systems onto the surfaces of superconducting materials. In certain superconductors, magnetic flux penetrates the material through tiny channels called Abrikosov vortices, each carrying exactly one quantum of magnetic flux. The magnetic field at the center of these vortices is extremely strong and confined to a region just a few nanometers wide — far smaller than what conventional magnets can achieve. This creates a unique laboratory for studying how molecular spins respond to intense, highly localized magnetic fields.
At the same time, the project aimed to harness this molecular spin sensing capability for a second purpose: investigating magnetism in atomically thin two-dimensional materials. Materials just one atom thick can exhibit exotic magnetic states — such as ferromagnetism or helimagnetic spirals — that are difficult to probe with conventional techniques. A magnetic molecule on the tip of a scanning probe microscope could serve as an ultrasensitive local probe of these magnetic states, opening new avenues for understanding and eventually exploiting 2D magnetism in future technologies.
The project had four main objectives: (1) upgrading the experimental equipment to enable new types of measurements, (2) mapping the magnetic field of vortices in high-temperature superconductors using a magnetic molecule attached to a scanning probe microscope tip, (3) studying how different molecular spin systems behave in these extreme local fields, and (4) applying the developed techniques to investigate magnetism in atomically thin two-dimensional materials. The fellowship was carried out at Aalto University, Finland.