Abstract
Fe (acceptor) and Nb (donor) doped epitaxial Pb(Zr0.2Ti0.8)O3 (PZT) films were grown on single crystal SrTiO3 substrates and their electric properties were compared to those of un-doped PZT layers deposited in similar conditions. All the films were grown from targets produced from high purity precursor oxides and the doping was in the limit of 1% atomic in both cases. The remnant polarization, the coercive field and the potential barriers at electrode interfaces are different, with lowest values for Fe doping and highest values for Nb doping, with un-doped PZT in between. The dielectric constant is larger in the doped films, while the effective density of charge carriers is of the same order of magnitude. An interesting result was obtained from piezoelectric force microscopy (PFM) investigations. It was found that the as-grown Nb-doped PZT has polarization orientated upward, while the Fe-doped PZT has polarization oriented mostly downward. This difference is explained by the change in the conduction type, thus in the sign of the carriers involved in the compensation of the depolarization field during the growth. In the Nb-doped film the majority carriers are electrons, which tend to accumulate to the growing surface, leaving positively charged ions at the interface with the bottom SrRuO3 electrode, thus favouring an upward orientation of polarization. For Fe-doped film the dominant carriers are holes, thus the sign of charges is opposite at the growing surface and the bottom electrode interface, favouring downward orientation of polarization. These findings open the way to obtain p-n ferroelectric homojunctions and suggest that PFM can be used to identify the type of conduction in PZT upon the dominant direction of polarization in the as-grown films.
Highlights
Pb(Zr,Ti)O3 (PZT) ceramics and thin films are studied for to their multifunctional properties, making them attractive for a wide variety of applications in electronics, energy, sensing, actuation, and others[1,2,3]
Good quality can be currently grown by pulsed laser deposition (PLD) on suitable single crystal substrates like SrTiO3 (STO)[29,30]
It was found that the electrical properties are significantly different for Fe and Nb doped PZT, respectively: the coercive field is lower in Fe doped PZT; the height of the potential barrier at the interface with SrRuO3 (SRO) electrodes is almost three times larger in Nb doped PZT; the concentration of charge carriers is slightly larger in Fe doped PZT, and the leakage current is with about 2 orders of magnitude larger in Fe doped PZT
Summary
Pb(Zr,Ti)O3 (PZT) ceramics and thin films are studied for to their multifunctional properties (reversible polarization under applied electric field; piezoelectricity; pyroelectricity; birefringence, etc.), making them attractive for a wide variety of applications in electronics (non-volatile memories, field effect transistors), energy (supercapacitors, photovoltaic effect), sensing (pyroelectric detectors, infrared camera), actuation (piezoelectric actuators), and others[1,2,3]. It is possible to study the effect of dopants, acceptor and donors, on the electrical properties of epitaxial PZT layers at doping levels that are around or below 1% atomic Another interesting aspect reported in the literature is that the orientation of polarization in the as-grown PZT layers can be controlled by changing the substrate or the bottom electrode. It was found that the electrical properties are significantly different for Fe and Nb doped PZT, respectively: the coercive field is lower in Fe doped PZT; the height of the potential barrier at the interface with SrRuO3 (SRO) electrodes is almost three times larger in Nb doped PZT; the concentration of charge carriers is slightly larger in Fe doped PZT, and the leakage current is with about 2 orders of magnitude larger in Fe doped PZT These are explained by the changes introduced by the two dopants in the electronic properties of PZT. It was found that the change of doping type affects the polarization orientation, with polarization upward in PZT-Nb and downward dominant in PZT-Fe
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