posted on 2023-03-29, 17:03authored byDeok-Yong Cho, Ki-jeong Kim, Kug-Seung Lee, Michael Lübben, Shaochuan Chen, Ilia Valov
Thin layers introduced
between a metal electrode and
a solid electrolyte
can significantly alter the transport of mass and charge at the interfaces
and influence the rate of electrode reactions. C films embedded in
functional materials can change the chemical properties of the host,
thereby altering the functionality of the whole device. Using X-ray
spectroscopies, here we demonstrate that the chemical and electronic
structures in a representative redox-based resistive switching (RS)
system, Ta2O5/Ta, can be tuned by inserting
a graphene or ultrathin amorphous C layer. The results of the orbitalwise
analyses of synchrotron Ta L3-edge, C K-edge, and O K-edge
X-ray absorption spectroscopy showed that the C layers between Ta2O5 and Ta are significantly oxidized to form COx and, at the same time, oxidize the Ta layers
with different degrees of oxidation depending on the distance: full
oxidation at the nearest 5 nm Ta and partial oxidation in the next
15 nm Ta. The depth-resolved information on the electronic structure
for each layer further revealed a significant modification of the
band alignments due to C insertion. Full oxidation of the Ta metal
near the C interlayer suggests that the oxygen-vacancy-related valence
change memory mechanism for the RS can be suppressed, thereby changing
the RS functionalities fundamentally. The knowledge on the origin
of C-enhanced surfaces can be applied to other metal/oxide interfaces
and used for the advanced design of memristive devices.