and showed a considerable increase

and showed a considerable increase in Z. Later, Lin-Chung
et al. [11] and Broido et al. [12] included the effects of
thermal transport in the finite barrier layers and carrier
tunneling between layers in the above model to get a
modified Z. Encouraged by these findings, various new
materials, having layered structure, have been investigated
in the last few years, which include NaCo2O4 [13],
(ZnO)mIn2O3 [14], CuAlO2 single crystal [15], etc.
Materials of delafossite structure MIMIIIO2 (where
MI=Cu, Ag, Pt, Pd; MIII=Al, Ga, In, Cr, Fe, Co, etc.)
possess natural layered structure [16–18]. Hence, they can
become promising thermoelectric materials according to
Hicks model. Polycrystalline CuAlO2 thin film is a p-type
transparent conducting oxide, which has tremendous potential
to be used in optoelectronic device technology [19–21].
In our previous works [22,23], we have reported the
synthesis and structural as well as electro-optical characteristics
of p-CuAlO2 thin film prepared by dc-sputtering
technique. In this communication, we have reported the
thermoelectric properties as well as electrical characteristics
of this technologically important material. Previously,
Koumoto et al. [15] studied the thermoelectric properties
of CuAlO2 single crystal and suggested that it may become
a good thermoelectric material. From literature survey, it
appears that no detail study on the thermoelectric properties
of CuAlO2 thin film has been reported so far. In this study,
we have prepared the films by dc-sputtering method. During
the synthesis process, the postdeposition annealing time (ta)
of the films in O2 atmosphere was taken as a varying
parameter, to observe any variation in the thermoelectric and
electrical properties in the films and tried to explain the
electrical transport mechanism therefrom. This study may
help to produce tailored material having improved thermoelectric
and electrical characteristics for better device
application.