Spintronics across molecular spin chains using solvent-free nanojunction processing.

The quantum properties of nano-objects, such as atoms or molecules, are typically manipulated using scanning tunnelling microscopes and lateral break junctions. The resulting nanotransport path is well established in these model devices. Societal applications require transposing this knowledge to nano-objects embedded within vertical solid-state junctions, which advantageously can harness spintronics to addressing these quantum properties thanks to ferromagnetic electrodes and high-quality interfaces. Here, one challenge is to ascertain the device's effective, buried nanotransport path. Another is to achieve a nanojunction comparising a molecular layer with high-quality interfaces. We've developed a low-tech, resist- and solvent-free technological process that can craft nanopillar devices from in-situ grown heterostructures, and use it to study magnetotransport between two Fe and Co ferromagnetic electrodes across a CoPc functional magnetic molecular layer. By identifying three magnetic units along the effective nanotransport path thanks to a macrospin model of magnetotransport, our experiments show how spin-flip transport across CoPc molecular spin chains promotes a specific magnetoresistance effect, and alters the nanojunction's magnetism through spintronic anisotropy. Our work elegantly connects the until now loosely associated concepts of spin-flip spectroscopy, magnetic exchange bias and magnetotransport due to molecular spin chains. We notably measure a 5.9meV energy barrier for magnetic decoupling between the Fe layer's buried atoms and those in contact with the CoPc layer forming the so-called 'spinterface'. This provides a first insight into the experimental energetics of this promising low-power information encoding unit.