The drive towards organic computing is gaining momentum. Interestingly, the building blocks
for such architectures is based on molecular ensembles extending from nucleic acids to synthetic
molecules. Advancement in this direction requires devising precise nanoscopic experiments and
model calculations to decipher the mechanisms governing the integration of a large number
of molecules over time at room-temperature. Here, we report on ultrahigh-resolution scanning
tunnelling microscopic measurements to register the motion of molecules in the absence of external
stimulus in liquid medium. We observe the collective behavior of individual molecules within a swarm
which constantly iterate their position to attain an energetically favourable site. Our approach
provides a consistent pathway to register molecular self-assembly in sequential steps from visualising
thermodynamically driven repair of defects up until the formation of a stable two-dimensional
configuration. These elemental findings on molecular surface dynamics, self-repair and intermolecular
kinetic pathways rationalised by atom-scale simulations can be explored for developing new models
in algorithmic self-assembly to realisation of evolvable hardware.
Funding
Study on Aerodynamic Characteristics Control of Slender Body Using Active Flow Control Technique