Novel Transformations of PbTiO3 with Pressure and Temperature

TL;DR

This study explores how lead titanate (PbTiO3) behaves under extreme pressures and temperatures, revealing phase stability, decomposition, and new polymorphs, with implications for its electronic properties and phase transitions.

Contribution

It provides new insights into PbTiO3's phase behavior under high pressure and temperature, including decomposition and novel PbO phases, supported by combined experimental and theoretical analysis.

Findings

PbTiO3 decomposes into PbO and TiO2 above 65 GPa at high temperature.

Distinct PbO phases, including a new delta phase, are stabilized by laser heating.

Alpha PbO undergoes metallization above 70 GPa, while delta and beta phases remain semiconducting.

Abstract

We investigated the behavior of lead titanate (PbTiO3) up to 100 GPa, both at room temperature and upon laser heating, using synchrotron X ray diffraction combined with density functional theory (DFT) computations. At the high pressure temperature (PT) conditions produced in laser heated diamond anvil cells, PbTiO3 dissociates into PbO and TiO2, consistent with our DFT computations showing that decomposition becomes enthalpically favored above 65 GPa. In contrast, on room temperature compression, PbTiO3 persists in the tetragonal I4mcm phase up to at least 100 GPa. Laser heating produces distinct PbO phases: a compressed form of alpha PbO and a previously unreported delta PbO polymorph, both of which transform to beta PbO on decompression. The calculations predict that alpha PbO undergoes pressure-induced band gap closure, metallizing above 70 GPa, whereas the delta and beta phases remain semiconducting with a band gap above 1 eV even at megabar pressures. The experimental and confirming theoretical results reveal an unanticipated dimension of the behavior of PbTiO3, showing that distinct equilibrium and metastable phases can be stabilized along different PT synthesis paths.