Abstract
Structural polymorphism is ubiquitous in physisorbed self-assembled monolayers formed at the solution–solid interface. One of the ways to influence network formation at this interface is to physically decouple the self-assembled monolayer from the underlying substrate thereby removing the influence of the substrate lattice, if any. Here we show a systematic exploration of self-assembly of a typical building block, namely 4-tetradecyloxybenzoic acid at the 1-phenyloctane–graphite interface in the presence and in the absence of a buffer layer formed by a long chain alkane, namely n-pentacontane. Using scanning tunneling microscopy (STM), three different structural polymorphs were identified for 4-tetradecyloxybenzoic acid at the 1-phenyloctane–graphite interface. Surprisingly, the same three structures were formed on top of the buffer layer, albeit at different concentrations. Systematic variation of experimental parameters did not lead to any new network in the presence of the buffer layer. We discovered that the self-assembly on top of the buffer layer allows better control over the nanoscale manipulation of the self-assembled networks. Using the influence of the STM tip, we could initiate the nucleation of small isolated domains of the benzoic acid on-command in a reproducible fashion. Such controlled nucleation experiments hold promise for studying fundamental processes inherent to the assembly process on surfaces.
Highlights
The ability of some molecules to crystalize in more than one type of packing – a property widely known as crystal polymorphism – is not limited to the realm of bulk (3D) crystals and extends to the 2D world of physisorbed self-assembled monolayers [1,2,3,4]
Before carrying out selfassembly experiments with n-C50 buffer layers, we systematically studied the concentration dependence of BA-OC14 assembly to comprehensively identify the different structures formed by BA-OC14 at the 1-phenyloctane–highly oriented pyrolytic graphite (HOPG) interface
What is the mechanism behind the on-command nucleation of BA-OC14 on the buffer layers? We propose that the stimuli provided, namely scanning at higher currents and the voltage pulsing, removes the residual layer of n-C50 molecules interacting with the monolayer of n-C50 adsorbed on the surface
Summary
The ability of some molecules to crystalize in more than one type of packing – a property widely known as crystal polymorphism – is not limited to the realm of bulk (3D) crystals and extends to the 2D world of physisorbed self-assembled monolayers [1,2,3,4]. Before carrying out selfassembly experiments with n-C50 buffer layers, we systematically studied the concentration dependence of BA-OC14 assembly to comprehensively identify the different structures formed by BA-OC14 at the 1-phenyloctane–HOPG interface.
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