posted on 2023-10-03, 20:33authored byRachel
S. Hendley, Lechuan Zhang, Michael A. Bevan
We report the controlled interfacial
assembly and reconfiguration
of rectangular prism colloidal particles between microstructures of
varying positional and orientational order including stable, metastable,
and transient states. Structurally diverse states are realized by
programming time dependent electric fields that mediate dipolar interactions
determining particle position, orientation, compression, and chaining.
We identify an order parameter set that defines each state as a combination
of the positional and orientational order. These metrics are employed
as reaction coordinates to capture the microstructure evolution between
initial and final states upon field changes. Assembly trajectory manifolds
between states in the low-dimensional reaction coordinate space reveal
a dynamic pathway map including information about pathway accessibility,
reversibility, and kinetics. By navigating the dynamic pathway map,
we demonstrate reconfiguration between states on minute time scales,
which is practically useful for particle-based materials processing
and device responses. Our findings demonstrate a conceptually general
approach to discover dynamic pathways as a basis to control assembly
and reconfiguration of self-organizing building blocks that respond
to global external stimuli.