Abstract
Electropolymerization has emerged as a versatile electrochemical strategy for creating functional films of conjugated polymers, offering molecular-level tunability and spatial control. Beyond its simplicity and reagent-free nature, this approach provides a unique window into how interfacial environments, charge-transfer kinetics, and molecular coupling collectively dictate polymer growth and functionality. Because the resulting material properties are rooted in the delicate interplay between interfacial structure and reaction mechanism, unraveling these correlations remains central to both mechanistic understanding and rational material design. Recent efforts, including copolymerization, templated electropolymerization, and layer-by-layer strategies, have expanded the accessible structural and functional landscape, yet precise control of molecular architecture at electrochemical interfaces continues to pose significant challenges. This Outlook highlights emerging mechanistic insights and underscores the transformative role of advanced in situ and operando characterization techniques in bridging nanoscale structural evolution with macroscopic electrochemical behavior, ultimately pointing toward a mechanism-guided framework for designing next-generation conjugated polymers.