Perovskite is a material with an almost ideal structure. The majority of high-temperature superconductors are perovskite-based due to their non-ideal structure. The material can also be used to produce flexible solar batteries without rare-earth metals, which reduces costs and enables large-scale manufacture.
One of the authors notes the manganite-like properties of perovskites: “This material exhibits many interesting and intriguing properties, most notably giant magnetoresistance. Many manganite properties are unknown, despite the fact that manganites have been studied for decades. We tried to work out what the conduction mechanism is of one of the most common compounds: Pr1-xCaxMnO3,” he says. All these features have been experimentally discovered, but the processes to explain these unique properties are unknown.
Semiconductors were discovered more than 150 years ago. Electricity was a new development at the time. It was obvious that there were isolators like rubber and glass, conductors like copper and gold, and some uncertain materials called semiconductors that did not fit into any category. The mechanisms of semiconductors remained unknown for about a century. It was not until the 1930s that the problem was solved and the first transistor was made. Today, it is difficult to imagine any electronic device without transistors.
Unfortunately, it is not possible to see charge movement in a material under a microscope. This is why researchers at Terahertz Spectroscopy Laboratory decided to use indirect detection methods. To test which particles are conductive, they applied different frequency voltages and measured the relationship between frequency and induced current. The scientists measured the frequency and temperature dependence of conductivity and permittivity in a broad frequency range to cover all the bases. Wide temperature ranges of the samples, from 10 to 300 K (-263 to 27 °C), were obtained to distinguish similar dependences of samples with different conduction mechanisms. But even this was insufficient to clarify the nature of charge carries. For this reason, researchers compared perovskites with different ratios of calcium (Ca) and praseodymium (Pr).
The group of scientists headed by Boris Gorshunov, Terahertz Spectroscopy Laboratory supervisor, (Lenar Kadyrov PhD, and laboratory scientists Elena Zhukova and Vladimir Anzin are also authors of this article) thus discovered that the charge carriers in Pr1-xCaxMnO3 perovskites are polarons. A polaron is an electron moving through the constituent atoms of a material, causing the neighboring positive charges to shift toward it and the neighboring negative charges to shift away. The properties of perovskites are ideal for electron-phonon (phonons are vibrations in a crystal lattice) coupling, determined by the interplay between symmetry breaking interactions. The researchers established that polarons move coherently (as one unit). That is to say, charge carriers behave more like uncoupled particles. The idea of coherence is applied in lasers, superconductors, highly accurate distance measurements, quantum calculations, and other areas.
Establishing how conduction occurs could help perovskite research projects and large-scale applications to progress. For example, there is already a high-efficiency, perovskite-based device for separating water into oxygen and hydrogen. Perovskites can also be used as LEDs, though they currently function only at the temperature of liquid nitrogen.
More information: L. S. Kadyrov et al, Bandlike electrical transport in Pr1-xCaxMnO3 manganites, Physical Review B (2016). DOI: 10.1103/PhysRevB.93.184303