The effective operation of atomic
layer deposition (ALD) feeding
system is the premise of realizing specific ALD processes. In the
present work, a detailed computational fluid dynamics (CFD) model
of the feeding system has been developed and validated, which accounts
for the roles of ALD valves and manifolds. A numerical simulation
of the compressible fluid flow and heat/mass transfer within the feeding
system was conducted. The dosing amounts and the spatiotemporal distributions
of the precursors can be accurately predicted using the CFD model,
as validated by experimental results. Different precursors, operating
conditions, and structures of the feeding system were simulated and
analyzed to examine the operating flexibility of the feeding system.
The simulation results can be adopted as the upstream boundary conditions
for simulations of the ALD process in the reaction chamber. The substrate-scale
simulation indicates that the effect of the feeding system on the
film deposition is highly related to the surface kinetics of ALD.
The present work can serve as a guide for the development and optimization
of different ALD-based processes via proper operation and even the
design of the feeding system.
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