posted on 2024-06-28, 18:04authored byVamseedhara Vemuri, Sean W. King, Ryan Thorpe, Andrew H. Jones, John T. Gaskins, Patrick E. Hopkins, Nicholas C. Strandwitz
Post deposition annealing of molecular layer-deposited
(MLD) hafnicone
films was examined and compared to that of hafnium oxide atomic layer-deposited
(ALD) films. Hafnicone films were deposited using tetrakis(dimethylamido)hafnium
(TDMAH), and ethylene glycol and hafnia films were deposited using
TDMAH and water at 120 °C. The changes in the properties of the
as-deposited hafnicone films with annealing were probed by various
techniques and then compared to the as-deposited and annealed ALD
hafnia films. In situ X-ray reflectivity indicated a 70% decrease
in thickness and ∼100% increase in density upon heating to
400 °C yet the density remained lower than that of hafnia control
samples. The largest decreases in thickness of the hafnicone films
were observed from 150 to 350 °C. In situ X-ray diffraction indicated
an increase in the temperature required for crystallization in the
hafnicone films (600 °C) relative to the hafnia films (350 °C).
The changes in chemistry of the hafnicone films annealed with and
without UV exposure were probed using Fourier transformed infrared
spectroscopy and X-ray photoelectron spectroscopy with no significant
differences attributed to the UV exposure. The hafnicone films exhibited
lower dielectric constants than hafnia control samples over the entire
temperature range examined. The CF4/O2 etch
rate of the hafnicone films was comparable to the etch rate of hafnia
films after annealing at 350 °C. The thermal conductivity of
the hafnicone films initially decreased with thermal processing (up
to 250 °C) and then increased (350 °C), likely due to porosity
generation and subsequent densification, respectively. This work demonstrates
that annealing MLD films is a promising strategy for generating thin
films with a low density and relative permittivity.