posted on 2021-10-15, 11:26authored byChristian
M. Heil, Arthi Jayaraman
In this paper, we
describe a computational method for analyzing
results from scattering experiments on dilute solutions of supraparticles,
where each supraparticle is created by the assembly of nanoparticle
mixtures. Taking scattering intensity profiles and nanoparticle mixture
composition and size distributions in each supraparticle as input,
this computational approach called computational reverse engineering
analysis for scattering experiments (CREASE) uses a genetic algorithm
to output information about the structure of the assembled nanoparticles
(e.g., real space pair correlation function, extent of nanoparticle
mixing/segregation, sizes of domains) within a supraparticle. We validate
this method by taking as input in silico scattering intensity profiles
from coarse-grained molecular simulations of a binary mixture of nanoparticles,
forming a close-packed structure and testing if our computational
method can correctly reproduce the nanoparticle structure observed
in those simulations. We test the strengths and limitations of our
method using a variety of in silico scattering intensity profiles
obtained from simulations of a spherical or a cubic supraparticle
comprising binary nanoparticle mixtures with varying chemistries,
with and without dispersity in sizes, that exhibit well-mixed to strongly
segregated structures. The strengths of the presented method include
its capability to analyze scattering intensity profiles even when
the wavevector q range is limited, to handily provide
all of the pairwise radial distribution functions, and to correctly
determine the extent of segregation/mixing of the nanoparticles assembled
in complex geometries.