Spin switching in electronic devices based on 2D assemblies of spin-crossover nanoparticles

TL;DR

This study investigates the electrical transport properties of 2D assemblies of spin-crossover nanoparticles, revealing a large conductance change near room temperature that depends on morphology and organization.

Contribution

It demonstrates unprecedented large conductance changes in 2D assemblies of spin-crossover nanoparticles, highlighting the influence of size and morphology on their electronic properties.

Findings

Large conductance change up to two orders of magnitude observed.

Conductance hysteresis correlates with nanoparticle morphology.

Size and morphology significantly influence spin-crossover transport properties.

Abstract

In this communication we study the transport properties of two-dimensional assemblies of [Fe(Htrz)2(trz)](BF4) spin-crossover nanoparticles (NPs) with two different morphologies. The NPs have been synthesized made in a similar manner than in our previous study in which single NPs were measured. We prepared free-standing self-assembled monolayer sheets of both SCO NPs formed at the air/liquid interface on holey carbon TEM grids to extract their global arrangement and NP size distributions by STEM-HAADF technique. The SCO NP systems present a rod-like shape and possess two different volumes, corresponding to lengths of 25 nm and 44 nm along the rod direction and average diameters of 10 nm and 6 nm respectively. In a similar manner, sheets of SCO NPs with the two different morphologies were electrically measured by contacting them on pre-patterned gold electrodes substrates. For both NP morphologies, a thermal hysteresis loop in the electrical conductance near room temperature was observed, which was correlated to their morphologies and 2D organization. The most remarkable result was the observation of an unprecedented large change in the electrical conductance of the two spin states, increasing by up to two orders of magnitude in the 2D assemblies of spin-crossover NPs. This value is significantly larger than that obtained in single-NP measurements (~ 3). Although such large conductance changes are not fully understood, our results point at important contributions from its size/morphology-dependence at the nanoscale.