posted on 2015-02-26, 00:00authored byD. Carta, G. Mountjoy, A. Regoutz, A. Khiat, A. Serb, T. Prodromakis
Metal–insulator–metal
(MIM) devices based on titanium
dioxide thin films exhibit resistive switching behavior (RS); i.e.,
they have the ability to switch the electrical resistance between
high-resistive states (HRS) and low-resistive states (LRS) by application
of an appropriate voltage. This behavior makes titanium dioxide thin
films extremely valuable for memory applications. The physical mechanism
behind RS remains a controversial subject but it has been suggested
that it could be interface-type, without accompanying structural changes
of the oxide, or filament-type with formation of reduced titanium
oxide phases in the film. In this work, X-ray absorption spectroscopy
(XAS) at the Ti K-edge (4966 eV) was used to characterize the atomic-scale
structure of a nonstoichiometric TiO2–x thin film before and after annealing and for the first time
after inclusion in a MIM device based on a Cr/Pt/TiO2–x/Pt stack developed on an oxidized silicon wafer.
The advantage of the XAS technique is that is element-specific. Therefore,
by tuning the energy to the Ti K-edge absorption, contributions from
the Pt, Cr, and Si in the stack are eliminated. In order to investigate
the structure of the film after electrical switching, XAS analysis
at the Ti K-edge was again performed for the first time on the Cr/Pt/TiO2–x/Pt stack in its virgin state and
after switching to LRS by application of an appropriate bias. X-ray
absorption near-edge structure (XANES) was employed to assess local
coordination and oxidation state of the Ti and extended X-ray absorption
fine structure (EXAFS) was used to assess bond distances, coordination
numbers, and Debye–Waller factors. XAS analysis revealed that
the as-deposited film is amorphous with a distorted local octahedral
arrangement around Ti (average Ti–O distance of 1.95 Å
and coordination number of 5.2) and has a majority oxidation state
of Ti4+ with a slight content of Ti3+. The film
remains amorphous upon insertion into the stack structure and after
electrical switching but crystallizes as anatase upon annealing at
600 °C. These results do not give any indication of the appearance
of conducting filaments upon switching and are more compatible with
homogeneous interface mechanisms.