Ablation of organic polymers is described on the basis of photothermal bond
breaking within the bulk material. Here, we assume a first-order chemical
reaction, which can be described by an Arrhenius law. Ablation starts when
the density of broken bonds at the surface reaches a certain critical value
.
In order to understand the ablation behavior near the threshold fluence, ph
i(th), non-stationary regimes must be considered. The present treatment rev
eals several qualitative differences with respect to models that treat abla
tion as a surface process: (i) Ablation starts sharply with a front velocit
y that has its maximum value just after the onset. (ii) The transition to t
he quasi-stationary ablation regime is faster. (iii) Near threshold, the ab
lated depth h has a square-root dependence on laser fluence, i.e., h propor
tional to (phi - phi(th))(1/2). The ablation velocity is very high even nea
r phi(th). (iv) With phi approximate to phi(th) ablation starts well after
the laser pulse. (v) The depletion of species is responsible for the Arrhen
ius tail observed with fluences phi less than or equal to phi(th). (vi) Res
idual modification of material has maximum near the threshold. (vii) Statio
nary regimes of ablation demonstrate change of effective activation energy
with laser intensity.
The model calculations are applied to Polyimide (Kapton(TM) H). Here, diffe
rences in single-pulse ablated depth determined from mass loss and profilom
etry should be about 10 nm.