Citation:Kafi, F.S.B., Jayathilekea, K.M.D.C., Wijesundera, R.P. and Siripala, W. 2015. Observation of interface modification of electrodeposited p-Cu2O thin films in an aqueous electrolyte, p. 209, In: Proceedings of the International Postgraduate Research Conference 2015 University of Kelaniya, Kelaniya, Sri Lanka, (Abstract), 339 pp.
Date:2015
Abstract:
Interface engineering via modification of semiconductor surfaces of junction devices is a
powerful technique to improve the performance of devices. In addition, semiconductor
material Cu2O has recently gained a considerable attention as a low cost semiconductor
material suitable for developing thin film solar cells, water splitting in photoelectrochemical
cells and gas sensors. Indeed, the possibility of relative band edge shifts of Cu2O with
suitable interfacing materials will pave the way for interface engineering to improve the
efficiency of those devices. In this study we have investigated this possibility of using
electrodeposited p-type cuprous oxide thin films deposited using a lactate bath containing 3
M sodium lactate and 0.4 M CuSO4 at various pH values. These Cu2O films were used in a
photolectrochemical cell to form semiconductor/electrolyte junctions in a 0.1 M sodium
acetate aqueous solution and then to measure the flat band potential variations with the pH of
the Cu2O film deposition baths. It was observed that pH value of the Cu2O film deposition
bath is very sensitive to the flat band potential. This result gives a direct evidence that the
surface of Cu2O film is modified at the Cu2O/electrolyte interface producing a relative band
edge shift yielding the observed flat band shifts. We observed a general trend of flat band
potential shift of about 350 mV in the positive direction, as the pH of the deposition bath was
changed from 7 to 12.5. The observed shift in the flat band potential in the positive direction
is very useful for the water splitting reaction because the valence band edge of Cu2O is
shifted positively relative to the oxygen redox potential. Our observation of highest
photoresponse for Cu2O thin films prepared at pH 13.5 is a direct evidence for the positive
shift of the band edges. The observation of the interface modification of Cu2O in aqueous
electrolyte may be further extended to other suitable interfaces for developing Cu2O based
junction devices.