4 research outputs found
First-principles study of oxygen vacancy defects in orthorhombic HfZrO/SiO/Si gate stack
The gate defect of the ferroelectric HfO-based Si field-effect transistor
(Si FeFET) plays a dominant role in its reliability issue. The first-principles
calculations are an effective method for the atomic-scale understanding of gate
defects. However, the first-principles study on the defects of FeFET gate
stacks, i.e., metal/orthorhombic-HfZrO/SiO/Si
structure, has not been reported so far. The key challenge is the construction
of metal/orthorhombic-HfZrO/SiO/Si gate stack models.
Here, we use the HfZrO(130) high-index crystal face as the
orthorhombic ferroelectric layer and construct a robust atomic structure of the
orthorhombic-HfZrO/SiO/Si gate stack without any gap
states. Its high structural stability is ascribed to the insulated interface.
The calculated band offsets show that this gate structure is of the type-I band
alignment. Furthermore, the formation energies and charge transition levels
(CTLs) of defects reveal that the oxygen vacancy defects are more favorable to
form compared with other defects such as oxygen interstitial and Hf/Zr vacancy,
and their CTLs are mainly localized near the Si conduction band minimum and
valence band maximum, in agreement with the reported experimental results. The
oxygen vacancy defects are responsible for charge trapping/de-trapping behavior
in Si FeFET. This work provides an insight into gate defects and paves the way
to carry out the first-principles study of ferroelectric HfO-based Si
FeFET.Comment: 18 pages, 5 figure