Irradiation driven molecular dynamics simulation of the FEBID process for Pt(PF$_3$)$_4$

TL;DR

This paper introduces a novel computational protocol using irradiation-driven molecular dynamics to simulate and analyze the formation of platinum nanostructures during the FEBID process, providing insights into the mechanisms of nanostructure growth.

Contribution

The paper develops a general computational methodology based on IDMD for simulating irradiation-driven nanostructure formation, specifically applied to Pt(PF₃)₄ on SiO₂, advancing FEBID modeling capabilities.

Findings

Simulated nucleation and growth of platinum nanostructures during FEBID.

Provided space-resolved metal content and growth rate data.

Revealed mechanisms of precursor fragmentation and cluster formation.

Abstract

This paper presents a detailed computational protocol for atomistic simulation of the formation and growth of metal-containing nanostructures during the Focused Electron Beam Induced Deposition (FEBID) process. The protocol is based upon the Irradiation-Driven Molecular Dynamics (IDMD) - a novel and general methodology for computer simulations of irradiation-driven transformations of complex molecular systems by means of the advanced software packages MBN Explorer and MBN Studio. Atomistic simulations performed following the formulated protocol provide valuable insights into the fundamental mechanisms of electron-induced precursor fragmentation and the related mechanism of nanostructure formation and growth using FEBID, which are essential for the further advancement of FEBID-based nanofabrication. The developed computational methodology is general and applicable to different precursor molecules, substrate types, irradiation regimes, etc. The methodology can also be adjusted to simulate the nanostructure formation by other nanofabrication techniques using electron beams, such as direct electron beam lithography. In the present study, the methodology is applied to the IDMD simulation of the FEBID of Pt(PF$_3$)$_4$ - a widely studied precursor molecule - on a SiO$_2$ surface. The simulations reveal the processes driving the initial phase of nanostructure formation during FEBID, including nucleation of Pt atoms, formation of small metal clusters on the surface, followed by their aggregation and the formation of dendritic platinum nanostructures. The analysis of the simulation results provides space resolved relative metal content, height and the growth rate of the deposits which represent valuable reference data for the experimental characterization of the nanostructures grown by FEBID.