Magnetic-Field Directed Vapor-Phase Assembly of Low Fractal Dimension Metal Nanostructures: Experiment and Theory

While gas-phase synthesis techniques offer a scalable approach to production of metal nanoparticles, directed assembly is challenging due to fast particle diffusion rates that lead to random Brownian aggregation. This work explores an electromagnetic-levitation technique to generate metal nanoparticle aggregates with fractal dimension (D-f) below that of diffusion limited assembly. We demonstrate that in addition to levitation and induction heating, the external magnetic field is sufficient to compete with random Brownian forces, which enables the formation of altered fractals. Ferromagnetic metals (Fe, Ni) form chain-like aggregates, while paramagnetic Cu forms compact nanoparticle aggregates with higher D-f values. We have also employed a Monte Carlo simulation to evaluate the necessary field strength to form linear chains in the gas phase.

Automated summary

Gas-phase synthesis techniques offer a scalable approach to production of metal nanoparticles, but directed assembly is challenging due to fast particle diffusion rates. This study explores the use of an electromagnetic-levitation technique to generate metal nanoparticle aggregates with altered fractal properties, competing with random Brownian forces. Ferromagnetic metals form chain-like aggregates, while paramagnetic metals form compact aggregates with higher fractal dimensions.