Diodes, memories, logic circuits,
and most other current information
technologies rely on the combined use of p- and n-type semiconductors.
Although oxide semiconductors have many technologically attractive
functionalities, such as transparency and high dopability to enable
their use as conducting films, they typically lack bipolar conductivity.
In particular, the absence of p-type semiconducting properties owing
to the innate electronic structures of oxides represents a bottleneck
for the development of practical devices. Here, bipolar semiconducting
properties are demonstrated in α-SnWO4 within a 100
°C temperature window after appropriate thermal treatment. Comprehensive
spectroscopic observations reveal that Sn4+ is present
in p-type α-SnWO4 in a notably greater quantity than
in n-type. This result strongly suggests that the Sn4+ substitutional
defects on the W6+ sites contribute to hole-carrier generation
in α-SnWO4. We also find that oxygen vacancies are
initially formed in Sn–O–W bonds and migrate to W–O–W
bonds with changes in semiconducting properties from p-type to n-type.
These findings suggest useful strategies for exploring p-type oxide
semiconductors and controlling their carrier type by utilizing the
octahedral structure.
The development of p-type oxide semiconductors has shown promise in overcoming limitations restricting the practical usage of oxide semiconductors and the realization of innovative functional devices. Through numerous studies based...
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