Fabrication of multilayer edge molecular electronics and spintronics devices

TL;DR

This paper presents a novel fabrication method for multilayer edge molecular electronics and spintronics devices, enabling molecular connections at tunnel junction edges with various metal electrodes, advancing the development of molecular-scale electronic and spintronic components.

Contribution

The authors introduce a simple liftoff-based fabrication technique to create exposed edges of tunnel junctions for molecular bridging, compatible with diverse electrodes and molecular solutions, including ferromagnetic ones.

Findings

Successfully bridged magnetic and non-magnetic molecules across AlOx barriers.

Demonstrated stability variations depending on electrode material.

Developed molecular solutions resistant to ferromagnetic electrodes.

Abstract

Advancement of molecular devices will critically depend on the approach to establish electrical connections to the functional molecule(s). We produced a molecular device strategy which is based on chemically attaching of molecules between the two magnetic/nonmagnetic metallic electrodes along the multilayer edge(s) of a prefabricated tunnel junction. Here, we present the fabrication methodology for producing these multilayer edge molecular electronics/spintronics devices (MEMEDs/MEMSDs) and details of the associated challenges and their solutions. The key highlight of our MEMED/MEMSD approach is the method of producing exposed side edge(s) of a tunnel junction for hosting molecular conduction channels by a simple liftoff method. The liftoff method ensured that along the tunnel junction edges, the minimum gap between the two metal electrodes equaled the thickness of the tunnel barrier. All of the tunnel junction test beds used a ~2 nm alumina (AlOx) tunnel barrier. We successfully bridged the magnetic organometallic molecular clusters and non-magnetic alkane molecules across the AlOx insulator along the exposed edges, to transform the prefabricated tunnel junction into the molecular electronics or spintronics devices. Tunnel junction test beds were fabricated with a variety of metal electrodes, such as NiFe, Co, Ni, Au, Ta, Cu and Si. Stability of ultrathin thin AlOx varied with the type of bottom metal electrodes used for making MEMED/MEMSD. Additionally, molecular solution used for bridging molecular channels in a MEMED was not compatible with all the metal electrodes; molecular solution resistant ferromagnetic electrodes were developed for the fabrication of MEMSDs. MEMSD approach offers an open platform to test virtually any combination of magnetic electrodes and magnetic molecules, including single molecular magnets.