Electron–ion coupling breaks energy symmetry in bistable organic electrochemical transistors

Organic electrochemical transistors are extensively studied for applications ranging from bioelectronics to analog and neuromorphic computing. Despite significant advances, the fundamental interactions between the polymer semiconductor channel and the electrolyte, which critically determine the device performance, remain underexplored. Here, we examine the coupling between the benchmark semiconductor PEDOT:PSS and an ionic liquid to explain the bistable and non-volatile behavior observed in OECTs. Using X-ray scattering and spectroscopy techniques, we demonstrate how the electrolyte modifies the channel composition, enhances molecular order, and reshapes the energetic landscape. Notably, the observed bistability arises from asymmetric and path-dependent energetics during doping and dedoping, resulting in two distinct paths, driven by a direct interaction between the electronic and ionic charge carriers. These findings highlight the electrolyte’s role in tuning charge carrier dynamics, positioning it as a powerful yet underutilized lever for enabling novel device functionalities. Mechanistic understanding of interactions between polymer semiconductor channel and electrolyte in organic electrochemical transistors remains limited. Here, X-ray scattering and spectroscopy reveal the origin of bistability and non-volatile behavior between semiconducting PEDOT:PSS and an ionic liquid.