Conductivity in organic semiconductors hybridized with the vacuum field

TL;DR

This study demonstrates that coupling organic semiconductors to the vacuum electromagnetic field significantly enhances their conductivity by creating hybridized states, offering a new approach to improve organic electronic devices.

Contribution

It introduces a novel method of increasing organic semiconductor conductivity through strong light-matter coupling, confirmed by experiments and theoretical modeling.

Findings

Conductivity increased by an order of magnitude at resonance.

Hybridized states extend over many molecules, enhancing delocalization.

Theoretical model confirms wave-function delocalization in hybrid states.

Abstract

Organic semiconductors have generated considerable interest for their potential for creating inexpensive and flexible devices easily processed on a large scale [1-11]. However technological applications are currently limited by the low mobility of the charge carriers associated with the disorder in these materials [5-8]. Much effort over the past decades has therefore been focused on optimizing the organisation of the material or the devices to improve carrier mobility. Here we take a radically different path to solving this problem, namely by injecting carriers into states that are hybridized to the vacuum electromagnetic field. These are coherent states that can extend over as many as 10^5 molecules and should thereby favour conductivity in such materials. To test this idea, organic semiconductors were strongly coupled to the vacuum electromagnetic field on plasmonic structures to form polaritonic states with large Rabi splittings ca. 0.7 eV. Conductivity experiments show that indeed the current does increase by an order of magnitude at resonance in the coupled state, reflecting mostly a change in field-effect mobility as revealed when the structure is gated in a transistor configuration. A theoretical quantum model is presented that confirms the delocalization of the wave-functions of the hybridized states and the consequences on the conductivity. While this is a proof-of-principle study, in practice conductivity mediated by light-matter hybridized states is easy to implement and we therefore expect that it will be used to improve organic devices. More broadly our findings illustrate the potential of engineering the vacuum electromagnetic environment to modify and to improve properties of materials.