Domain-induced control of latent heat in freestanding BaTiO$_3$ membranes
Tapas Bar, David Pesquera, Arnau Villalobos-Martin, Cristian Rodriguez-Tinoco, Umair Saeed + 9 more
TLDR
Domain morphology, not thickness, dictates the transition order and latent heat in freestanding BaTiO$_3$ membranes, enabling caloric effect control.
Key contributions
- Shows domain morphology, not thickness or boundary conditions, controls ferroelectric transition order.
- Thick membranes with large domains exhibit clear latent heat, indicating a first-order transition.
- Thinner membranes with dense 180° domains show continuous transitions despite identical structural change.
- Reduced domain size lowers the free-energy barrier, rounding nominally first-order instabilities.
Why it matters
This paper redefines the understanding of ferroelectric phase transitions in oxide membranes, shifting focus from thickness to domain morphology. It provides crucial design guidelines for engineering domain patterns to enhance caloric effects, impacting energy-efficient cooling technologies.
Original Abstract
Thin ferroelectric BaTiO$_3$ films often exhibit continuous transitions instead of the first-order behavior of bulk crystals, a discrepancy usually attributed to epitaxial strain or dimensionality. Using quasi-adiabatic nanocalorimetry on freestanding BaTiO$_3$ membranes-free of clamping and substrate heat sinking-we show that domain morphology, not thickness or boundary conditions, controls the transition order. Thick membranes with large, monodomain-like regions display clear latent heat, whereas thinner membranes with dense 180$^{\circ}$ domain patterns show a continuous transition despite undergoing the same tetragonal-cubic structural change confirmed by x-ray diffraction. Piezoresponse force microscopy links this behavior to domain-size evolution, and a Ginzburg-Landau analysis demonstrates how reduced domain size lowers the free-energy barrier, rounding a nominally first-order instability. These results identify domain morphology as the key determinant of ferroelectric transition order in oxide membranes and establish design guidelines for enhancing caloric effects through domain engineering.
📬 Weekly AI Paper Digest
Get the top 10 AI/ML arXiv papers from the week — summarized, scored, and delivered to your inbox every Monday.