A Route Toward the On-Surface Synthesis of Organic Ferromagnetic Quantum Spin Chains

TL;DR

This paper demonstrates the on-surface synthesis of organic ferromagnetic quantum spin chains using dibenzotriangulene, achieving strong ferromagnetic coupling and high-spin ground states, advancing the development of organic magnetic materials.

Contribution

It introduces a novel synthetic strategy for creating purely organic ferromagnetic spin chains with direct sublattice coupling, leading to high-spin states and strong ferromagnetic exchange.

Findings

Successfully synthesized ferromagnetic dimers and trimers with high-spin ground states.

Confirmed strong intermolecular ferromagnetic exchange of 7 meV.

Provided insights into sublattice coupling effects on organic magnetism.

Abstract

Engineering sublattice imbalance is an intuitive way to induce high-spin ground states in bipartite polycyclic conjugated hydrocarbons (PCHs). Such high-spin molecules can be employed as building blocks of quantum spin chains, which are outstanding platforms to study many-body physics and fundamental models in quantum magnetism. Recent reports on the bottom-up synthesis of antiferromagnetic molecular spin chains provided insights into paradigmatic quantum phenomena such as fractionalization. In contrast to antiferromagnetism, demonstration of ferromagnetic coupling between PCHs has been scarce. Previous attempts in this direction were limited by the formation of non-benzenoid rings leading to spin quenching, or the use of spacer motifs that considerably weaken the magnitude of ferromagnetic exchange. Here, we demonstrate the on-surface synthesis of short ferromagnetic spin chains based on dibenzotriangulene (DBT), a PCH with a triplet ground state. Our synthetic strategy centers on achieving a direct (that is, without a spacer motif) majority-minority sublattice coupling between adjacent units. This leads to a global sublattice imbalance in spin chains scaling with the chain length, and therefore a ferromagnetic ground state with a strong intermolecular ferromagnetic exchange. By means of scanning probe measurements and multiconfigurational quantum chemistry calculations, we analyze the electronic and magnetic properties of ferromagnetic dimers and trimers of DBT, and confirm their quintet and septet ground states, respectively, with an intermolecular ferromagnetic exchange of 7 meV. Furthermore, we elucidate the role of sublattice coupling on magnetism through complementary experiments on antiferromagnetic DBT dimers with majority-majority and minority-minority couplings. We expect our proof-of-principle study to provide impetus for the design of purely organic ferromagnetic materials.