Size-Dependent Lattice Pseudosymmetry for Frustrated Decahedral Nanoparticles

TL;DR

This study uses advanced electron microscopy to analyze size-dependent lattice pseudosymmetry in decahedral nanoparticles, revealing how structural heterogeneity diminishes with size and identifying a transition in internal symmetry.

Contribution

It provides the first detailed size-resolved structural characterization of frustrated decahedral nanoparticles using 4D-STEM strain mapping, uncovering size-dependent symmetry and phase transformation patterns.

Findings

Lattice heterogeneity decreases with increasing nanoparticle size.

A crossover at 35 nm particle size marks a shift in internal symmetry.

Distinct local lattice phase transformations between FCC and BCT observed.

Abstract

Geometric frustration is a widespread phenomenon in physics, materials science, and biology, occurring when the geometry of a system prevents local interactions from being all accommodated. The resulting manifold of nearly degenerate configurations can lead to complex collective behaviors and emergent pseudosymmetry in diverse systems such as frustrated magnets, mechanical metamaterials, and protein assemblies. In synthetic multi-twinned nanomaterials, similar pseudosymmetric features have also been observed and manifest as intrinsic lattice strain. Despite extensive interest in the stability of these nanostructures, a fundamental understanding remains limited due to the lack of detailed structural characterization across varying sizes and geometries. In this work, we apply four-dimensional scanning transmission electron microscopy strain mapping over a total of 23 decahedral nanoparticles with edge lengths, d, between 20 and 55 nm. From maps of full 2D strain tensor at nanometer spatial resolution, we reveal the prevalence of heterogeneity in different modes of lattice distortions, which homogenizes and restores symmetry with increasing size. Knowing the particle crystallography, we reveal distinctive spatial patterns of local lattice phase transformation between face-centered cubic and body-centered tetragonal symmetries, with a contrast between particles below and above d of 35 nm. The results suggest a cross-over size of the internal structure occurs, as particles shape transition from modified-Wulff shape favored at nanoscale to faceted, pentagonal bipyramidal shape. Ultimately, our 4D-STEM mapping provides new insight to long-standing mysteries of this historic system and can be widely applicable to study nanocrystalline solids and material phase transformation that are important in catalysis, metallurgy, electronic devices, and energy storage materials.