Unravelling the Pathway Complexity in Conformationally Flexible N-Centered Triarylamine Trisamides.

Abstract

Two families of C 3‐symmetrical triarylamine‐trisamides comprising a triphenylamine‐ or a tri(pyrid‐2‐yl)amine core are presented. Both families self‐assemble in apolar solvents via cooperative hydrogen‐bonding interactions into helical supramolecular polymers as evidenced by a combination of spectroscopic measurements, and corroborated by DFT calculations. The introduction of a stereocenter in the side chains biases the helical sense of the supramolecular polymers formed. Compared to other C 3‐symmetrical compounds, a much richer self‐assembly landscape is observed. Temperature‐dependent spectroscopy measurements highlight the presence of two self‐assembled states of opposite handedness. One state is formed at high temperature from a molecularly dissolved solution via a nucleation–elongation mechanism. The second state is formed below room temperature through a sharp transition from the first assembled state. The change in helicity is proposed to be related to a conformational switch of the triarylamine core due to an equilibrium between a 3:0 and a 2:1 conformation. Thus, within a limited temperature window, a small conformational twist results in an assembled state of opposite helicity.