Thermal Atomic Layer Etching of Aluminum Oxide (Al2O3) Using Sequential Exposures of Niobium Pentafluoride
(NbF5) and Carbon Tetrachloride (CCl4): A Combined
Experimental and Density Functional Theory Study of the Etch Mechanism
posted on 2021-04-09, 13:33authored byVarun Sharma, Simon D. Elliott, Tom Blomberg, Suvi Haukka, Michael E. Givens, Marko Tuominen, Mikko Ritala
Thermal atomic layer
etching (ALEt) of amorphous Al2O3 was performed
by alternate exposures of niobium pentafluoride
(NbF5) and carbon tetrachloride (CCl4). The
ALEt of Al2O3 is observed at temperatures from
380 to 460 °C. The etched thickness and the etch rate were determined
using spectroscopic ellipsometry and verified by X-ray reflectivity.
The maximum etch rate of about 1.4 Å/cycle and a linear increase
of the removed film thickness with the number of etch cycles were
obtained at a temperature of 460 °C. With the help of density
functional theory calculations, an etch mechanism is proposed where
NbF5 converts part of the Al2O3 surface
into an AlF3 or aluminum oxyfluoride layer, which upon
reacting with CCl4 is converted into volatile halide-containing
byproducts, thus etching away the converted portion of the material.
Consistent with this, a significant surface fluorine content of about
55 at. % was revealed when the elemental depth profile analysis of
a thick NbF5-treated Al2O3 layer
was performed by X-ray photoelectron spectroscopy. The surface morphology
of the reference, pre-, and postetch Al2O3 surfaces
was analyzed using atomic force microscopy and bright-field transmission
electron microscopy. Moreover, it is found that this process chemistry
is able to etch Al2O3 selectively over silicon
dioxide (SiO2) and silicon nitride (Si3N4).