Manipulation and detection of spin state of Iron-Porphyrin by dedicated chemisorption on magnetic substrates

TL;DR

This paper demonstrates how chemisorption on magnetic substrates can stabilize high spin states in iron porphyrin molecules, enabling spin manipulation crucial for molecular spintronics, using ab initio calculations and proposed detection methods.

Contribution

It introduces a method to switch the spin state of iron porphyrin via chemisorption on magnetic substrates, supported by detailed ab initio analysis.

Findings

High spin state (S=2) stabilized on magnetic substrates

Strong covalent interaction increases Fe-N bond lengths

Detection of spin state change via X-ray magnetic circular dichroism, Raman, STM

Abstract

One of the key factors behind the rapid evolution of molecular spintronics is the efficient realization of spin manipulation of organic molecules with a magnetic center. The spin state of such molecules may depend crucially on the interaction with the substrate on which they are adsorbed. In this letter, we demonstrate, using ab initio density functional calculations, that the stabilization of a high spin state of an iron porphyrin (FeP) molecule can be achieved via a dedicated chemisorption on magnetic substrates of different species and orientations. It is shown that the strong covalent interaction with the substrate increases Fe-N bond lengths in FeP and hence a switching to a high spin state (S=2) from a low spin state (S=1) is achieved. A ferromagnetic exchange interaction is established through a direct exchange between Fe and substrate magnetic atoms as well as through an indirect exchange via the N atoms in FeP. The mechanism of exchange interaction is further analyzed by considering structural models constructed from ab initio calculations. Finally, we illustrate the possibility of detecting a change in the molecular spin state by x-ray magnetic circular dichroism, Raman spectroscopy and spin-polarized scanning tunneling microscopy.