Backbone coplanarity manipulation via hydrogen bonding to boost the n-type performance of polymeric mixed conductors operating in aqueous electrolyte

The development of high-performance n-type semiconducting polymers remains a significant challenge. Reported here is the construction of a coplanar backbone via intramolecular hydrogen bonds to dramatically enhance the performance of n-type polymeric mixed conductors operating in aqueous electrolyte. Specifically, glycolated naphthalene tetracarboxylicdiimide (gNDI) couples with vinylene and thiophene to give gNDI-V and gNDI-T, respectively. The hydrogen bonding functionalities are fused to the backbone to ensure a more coplanar backbone and much tighter pi-pi stacking of gNDI-V than gNDI-T, which is evidenced by density functional theory simulations and grazing-incidence wide-angle X-ray scattering. Importantly, these copolymers are fabricated as the active layer of the aqueous-based electrochromic devices and organic electrochemical transistors (OECTs). gNDI-V exhibits a larger electrochromic contrast (& UDelta;T = 30%) and a higher coloration efficiency (1988 cm(2) C-1) than gNDI-T owing to its more efficient ionic-electronic coupling. Moreover, gNDI-V gives the highest electron mobility (0.014 cm(2) V-1 s(-1)) and mu C* (2.31 FV-1 cm(-1) s(-1)) reported to date for NDI-based copolymers in OECTs, attributed to the improved thin-film crystallinity and molecular packing promoted by hydrogen bonds. Overall, this work marks a remarkable advance in the n-type polymeric mixed conductors and the hydrogen bond functionalization strategy opens up an avenue to access desirable performance metrics for aqueous-based electrochemical devices.

Automated summary

This study presents a significant advancement in high-performance n-type semiconducting polymers by constructing a coplanar backbone through intramolecular hydrogen bonds. The resulting polymers exhibit enhanced performance in aqueous electrolyte, with higher electrochromic contrast and coloration efficiency, as well as improved electron mobility and mu C* values. The hydrogen bond functionalization strategy opens up new possibilities for achieving desirable performance metrics in aqueous-based electrochemical devices.