Domain-Enhanced Interlayer Coupling in Ferroelectric/Paraelectric Superlattices

Abstract: We investigate the ferroelectric phase transition and domain formation in a periodic superlattice consisting of alternate ferroelectric (FE) and paraelectric (PE) layers of nanometric thickness. We find that the polarization domains formed in the different FE layers can interact with each other via the PE layers. By coupling the electrostatic equations with those obtained by minimizing the Ginzburg-Landau functional we calculate the critical temperature of transition Tc as a function of the FE/PE superlattice … Show more

“…Ferroelectric domains are generally smaller than ferromagnetic domains [18][19][20][21], but the ferroelectric domains in BFO are noticeably bigger, and close to the domain size of magnetic Co. This suggests a higher energy cost of the domain walls [21,22], consistent with a strong magnetoelectric coupling at the wall [6]. This contrasts with the apparently low intrinsic magnetoelectric coupling of the bulk material [23], and underlines the interest of domain walls as multiferroic entities in their own right [24].…”

Fractal Dimension and Size Scaling of Domains in Thin Films of MultiferroicBiFeO3

“…Ferroelectric domains are generally smaller than ferromagnetic domains [18][19][20][21], but the ferroelectric domains in BFO are noticeably bigger, and close to the domain size of magnetic Co. This suggests a higher energy cost of the domain walls [21,22], consistent with a strong magnetoelectric coupling at the wall [6]. This contrasts with the apparently low intrinsic magnetoelectric coupling of the bulk material [23], and underlines the interest of domain walls as multiferroic entities in their own right [24].…”

Fractal Dimension and Size Scaling of Domains in Thin Films of MultiferroicBiFeO3

“…The spatial distribution of polarization P and electric potential ϕ (f) in the ferroelectric region (Ω f ) are described by the coupled electrostatic and nonlinear Ginsburg-Landau equations [10,11] …”

Stability of Vortex Phases in Ferroelectric Easy-Plane Nano-Cylinders

“…This leads to the tantalizing prospect that superlattices can be produced in which electric-field induced phase transitions yield enhanced piezoelectric properties. A second potential origin of the nonlinearity at low fields lies in the decomposition of the polarization of the film into domains at zero field, an effect which has previously been surmised based on the static properties of superlattices [16,17]. Further investigation will give more detailed insights into understanding the possible role of superlattice phase transitions under applied electric field.…”

Piezoelectricity in the Dielectric Component of Nanoscale Dielectric-Ferroelectric Superlattices