The atomic layer etching (ALE) of AlF3 was demonstrated using sequential thermal reactions with Sn(acac), and hydrogen fluoride (HE) as the reactants. AlF3 ALE is the first example of the thermal ALE of a metal fluoride. AlF3 ALE was investigated using in situ quartz crystal microbalance (QCM) and Fourier transform infrared (FTIR) measurements at temperatures from 150 to 250 degrees C. The QCM studies observed that AlF3 was etched linearly with atomic level precision versus number of sequential reactant cycles. QCM investigations also revealed that the sequential Sn(acac), and HF reactions were self-limiting versus reactant exposure. The FTIR spectroscopic analysis observed AlF3 etching by monitoring the loss of absorbance of AlF stretching vibrations in the AlF3 film. The FTIR studies also suggested that the Sn(acac)(2) reaction is self-limiting because of the buildup of acac-containing species on the AlF3 surface. The QCM measurements determined that the mass change per cycle (MCPC) increased with temperature from 2.0 ng/(cm(2) cycle) at 150 degrees C to -18.2 ng/(cm(2) cycle) at 250 degrees C. These MCPC values are equivalent to etch rates from 0.069 angstrom/cycle at 150 degrees C to 0.63 angstrom/cycle at 250 degrees C. In the proposed reaction mechanism for AlF3 ALE, the Sn(acac)(2) reactant accepts fluorine from AF(3) and donates acac to the surface. This reaction is believed to yield SnE(acac) and AlF(acac)(2) as volatile reaction products. The QCM and FTIR results suggest that the HF reaction converts AlF2(acac)* surface intermediates to AlE3* and volatile acacH reaction products. The ALE of other metal fluorides using Sn(acac)(2) and HF should be possible by a similar mechanism.

• 出版日期2015-11-12