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Abstract
A molecular level understanding of surface chemistry involved in the focused electron beam induced deposition (FEBID)
with metalorganic molecules is crucial for enhancing metal content in the nanostructures. Here we investigate the FEBID
process of trimethyl(methylcyclopentadienyl)platinum(IV) [MeCpPtMe₃] using focused electron beam induced mass
spectrometry (FEBiMS), a recently developed in situ analytical technique. A comparison with gas-phase electron impact
fragmentation, along with density-functional-theoretical calculations and molecular dynamics simulations are presented.
Our results indicate that charged fragments generated via dissociative ionization exhibit strong adsorption to the substrate
and lack sufficient kinetic energy to desorb, suggesting that the most observed charged species during FEBID originate
from gas-phase fragmentation above the surface. Furthermore, our study proposes processes like charge neutralization
and dissociative recombination, mechanisms not previously considered in FEBID, could be significant contributors for
increasing metal content in the resulting nanostructures.
