Spontaneous Transition between Multiple Conductance States and Rectifying Behaviors in an Artificial Single‐Molecule Funnel

It has long been an aspirational goal to create artificial channel structures that replicate the feat achieved by ion channel proteins. Biological ion channels occasionally demonstrate multiple conductance states (known as subconductance), remaining a challenging property to achieve in artificial channel molecules. We report a funnel‐shaped single‐molecule channel constructed by an electron‐deficient macrocycle and two electron‐deficient aromatic imide arms. Planar lipid bilayer measurements reveal distinct current recordings, including a closed state, two conducting states, and spontaneous transitions between the three states, resembling the events seen in biological ion channels. The transitions result from conformational changes induced by chloride transport in the channel molecule. Both opening states show a non‐linear and rectifying I–V relationship, indicating voltage‐dependent transport due to the asymmetrical channel structure. This work could enhance our understanding of ion permeation and channel opening mechanism. An artificial funnel‐shaped single‐molecule channel was constructed by an electron‐deficient macrocycle and two electron‐deficient aromatic imide arms. This molecular funnel exhibited multiple conducting states and spontaneous transitions between them, as well chloride‐selective transport ability and voltage‐dependent gating property (rectification) due to the asymmetrical channel structure.