Tailoring
of crystalline phases and dielectric properties of ZrO2 thin films are demonstrated by capping a nanoscale TiN layer
prepared by plasma-enhanced atomic layer deposition. The in-plane
tensile strain induced by the TiN capping layer gives rise to the
dramatic paraelectric-to-antiferroelectric phase transformation in
ZrO2 and the significant capacitance enhancement up to
209%. The result is attributed to the formation of the ZrO2 tetragonal phase with the out-of-plane compressive strain due to
TiN capping and the presence of interfacial TiO
x
N
y
, as revealed by nanobeam
electron diffraction, X-ray diffraction, and X-ray photoelectron spectroscopy.
The results demonstrate that the as-deposited TiN capping layer can
effectively modulate the dielectric properties of nanoscale thin films
without any postannealing treatment, which is very beneficial for
the back-end-of-line process integration and numerous applications
including supercapacitors, microelectromechanical systems, energy
conversion, and nanoelectronics.
For high-performance Ge-based transistors, one important point of focus is interfacial germanium oxide (GeOx). An AlN buffer layer effectively suppresses the interfacial GeOx, and produces a significant enhancement of the electrical characteristics.
Conformal atomic
layer etching (cALE) of Si is realized on the
basis of layer-by-layer self-limiting deposition and self-stop etching
processes at low temperatures. In each cALE cycle, a conformal oxide
layer was prepared by atomic layer deposition (ALD) on Si, resulting
in the formation of an ultrathin SiOx interfacial layer between the
oxide and Si. Afterward, the oxide and interfacial layers are removed
by self-stop wet chemical etching, leading to the cALE of Si. The
etching depth exhibits high linearity with respect to the applied
cALE cycles, revealing a precise etching rate of a few angstroms per
cALE cycle. The AFM measurement shows a low surface roughness after
the cALE process as compared with other etching methods. Moreover,
the evidence of conformal etching of cALE is provided by the TEM images
of fin/trench structures. Also, the high-resolution TEM image demonstrates
a smooth and damage-free Si surface after the cALE process. This layer-by-layer,
conformal, self-limiting, self-stop, and damage-free cALE technique
is highly beneficial to advanced semiconductor fabrication technology
for next-generation atomic-scale electronics.
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