Litcius/Paper detail

Growth of two-dimensional covalent organic frameworks on substrates: insight from microsecond atomistic simulations

Zilin Wang, Hong Du, Austin M. Evans, Xiaojuan Ni, Jean‐Luc Brédas, Haoyuan Li

2024Chemical Science13 citationsDOIOpen Access PDF

Abstract

-phenylene on metal substrates, closely mimicking experimental conditions. Our improved approach highlights that 2D polymerization occurs through monomer addition and island coalescence, with a pre-bonding stage allowing monomers/oligomers to dynamically adjust their configurations to the expanding island structures. Our results elucidate the mechanisms underlying the formation of vacancy and dislocation defects during 2D polymerization as well as their healing processes. Overall, our findings underscore the significant roles that high surface mobility, effective monomer-substrate anchoring, high framework rigidity, moderate monomer coordination, and low bonding rate play in forming large, extended 2D crystals while suppressing vacancy and dislocation defects. We demonstrate how these factors can be tuned through substrate selection, deposition rate modulation, and temperature control, thereby offering valuable insight for strategically optimizing on-surface 2D polymerizations.

Topics & Concepts

MicrosecondCovalent bondMolecular dynamicsNanotechnologyChemical physicsMaterials scienceChemistryComputational chemistryPhysicsOrganic chemistryAstronomyCovalent Organic Framework ApplicationsSurface Chemistry and CatalysisBlock Copolymer Self-Assembly
Growth of two-dimensional covalent organic frameworks on substrates: insight from microsecond atomistic simulations | Litcius