Ferroelectric materials bring new opportunities for self-powdered
photodetectors, taking advantage of their anomalous bulk photovoltaic
effect. However, ferroelectric-based photodetectors suffer from relatively
poor responsivity and detectivity due to obstacles of low electrical
conductivity and low photoelectric conversion ability. The present
work proposes a strategy based on heterovalent ion Ce-doping into
BaTiO3 (Ce-BTO) that gives rise to a good room temperature
conductivity combined with a significant PTCR (positive temperature
coefficient of resistivity) effect. By utilizing a Ce-BTO PTCR semiconductor,
a high-performance self-powered photodetector ITO/Ce-BTO/Ag is fabricated,
demonstrating a polarity-switchable photoresponse with the change
of wavelength due to the competition between hot electrons induced
by the Ag plasmonic effect and electron–hole pairs separated
by a Schottky barrier. Moreover, benefiting from the reduced bandgap
and the introduced impurity states, good responsivity (9.85 ×
10–5 A/W) and detectivity (1.25 × 1010 Jones) as well as fast response/recovery time (83/47 ms) is achieved
under 450 nm illumination. Finally, four representative logic gates
(“OR”, “AND”, “NOR”, and
“NAND”) are demonstrated with one photodetector via
the bipolar photoresponse. This work opens an avenue to promote the
application of PTCR semiconductors in optoelectronics, offering a
conceivable means toward high-performance self-powered photodetectors.