Macropore formation in p-type silicon: toward the modeling of morphology
The formation of macropores in silicon during electrochemical etching
processes has attracted much interest. Experimental evidences indicate
that charge transport in silicon and in the electrolyte should
realistically be taken into account in order to be able to describe
the macropore morphology. However, up to now, none of the existing
models has the requested degree of sophistication to reach such a goal.
Therefore, we have undertaken the development of a mathematical model
(phase-field model) to describe the motion and shape of the
silicon/electrolyte interface during anodic dissolution. It is
formulated in terms of the fundamental expression for the
electrochemical potential and contains terms which describe
the process of silicon dissolution during electrochemical
attack in a hydrofluoric acid (HF) solution. It should allow
us to explore the influence of the physical parameters on the
etching process and to obtain the spatial profiles across the
interface of various quantities of interest, such as the hole
concentration, the current density, or the electrostatic potential.
As a first step, we find that this model correctly describes
the space charge region formed at the silicon side of the interface.