Sparking mashups to form multifunctional alloy nanoparticles

TL;DR

This paper introduces a novel 'sparking mashups' technique for synthesizing multifunctional alloy nanoparticles, enabling the creation of high-entropy alloys with unprecedented compositions and stability, advancing catalysis and nanoprinting applications.

Contribution

The study presents a new vapor-solid transformation method using rapid quenching and oscillatory sparks to produce stable, diverse alloy nanoparticles, including previously unalloyed elemental combinations.

Findings

Successfully synthesized 55-element alloy nanoparticles.

Achieved thermal stability in ultrasmall alloy NPs at room temperature.

Demonstrated applications in fuel-cell catalysis and 3D nanoprinting.

Abstract

Synthesizing unconventional alloys remains challenging owing to seamless interactions between kinetics and thermodynamics. High entropy alloys (HEAs), for example, draw a fundamentally new concept to enable exploring unknown regions in phase diagrams. The exploration, however, is hindered by traditional metallurgies based on liquid-solid transformation. Vapor-solid transformation that is permissible on pressure-temperature phase diagrams, offers the most kinetically efficient pathway to form any desired alloy (e.g., HEA). Here, we report that a technique called "sparking mashups", which involves a rapidly quenched vapor source and induces unrestricted mixing for alloying 55 distinct types of ultrasmall nanoparticles (NPs) with controllable compositions. Unlike the precursor feed in wet chemistry, a microseconds-long oscillatory spark controls the vapour composition, which is eventually retained in the alloy NPs. The resulting NPs range from binary to HEAs with marked thermal stability at room temperature. We show that a nanosize-effect ensures such thermal stability and mimics the role of mixing entropy in HEAs. This discovery contradicts the traditional "smaller is less stable" view while enabling the elemental combinations that have never been alloyed to date. We even break the miscibility limits by mixing bulk-immiscible systems in alloy NPs. As powerful examples, we demonstrate the alloy NPs as both high-performance fuel-cell catalysts and building blocks for three-dimensional (3D) nanoprinting to construct HEA nanostructure arrays of various architectures and compositions. Our results form the basis of new rules for guiding HEA-NP synthesis and advancing catalysis and 3D printing to new frontiers.