Your search keyword '"Maguire, Jesi R."' showing total 2 results

1. Imaging Ferroelectrics: Reinterpreting Charge Gradient Microscopy as Potential Gradient Microscopy.

Author

Maguire, Jesi R., Waseem, Hamza, McQuaid, Raymond G. P., Kumar, Amit, Gregg, J. Marty, and Cochard, Charlotte

Subjects

LITHIUM niobate, KELVIN probe force microscopy, FERROELECTRIC crystals, MICROSCOPY, ATOMIC force microscopy, BARIUM titanate

Abstract

Charge gradient microscopy (CGM) is a scanning probe imaging mode, particularly well‐suited for the characterization of ferroelectrics. The implementation of the technique is straightforward; it involves monitoring currents that spontaneously develop between a passive conducting atomic force microscopy tip and Earth, as the tip is scanned across the specimen surface. However, details on the fundamental origin of contrast and what images mean, in terms of associated ferroelectric microstructures, are not yet fully understood. Here, by comparing information from CGM and Kelvin probe force microscopy, obtained from the same sets of ferroelectric domains (in both lithium niobate and barium titanate), it is shown that CGM reasonably reflects the spatial derivative of the measured surface potential. This is conceptually different from measuring local gradients in the surface bound‐charge density or in any associated screening charges: after all, clear CGM signals are seen, even when polarization is entirely in‐plane (where the bound charge density is uniformly zero, but gradients in surface potential are still fully expected). It is therefore suggested that CGM in ferroelectrics may be more accurately called potential gradient microscopy. [ABSTRACT FROM AUTHOR]

Published

2022

2. Anisotropic, meandering domain microstructure in the improper ferroelectric CsNbW2O9.

Author

McCartan, Shane J., Turner, Patrick W., McNulty, Jason A., Maguire, Jesi R., McCluskey, Conor J., Morrison, Finlay D., Gregg, J. Marty, and MacLaren, Ian

Subjects

PIEZORESPONSE force microscopy, DOMAIN walls (String models), LEAD titanate, ATOMIC displacements, TRANSMISSION electron microscopy, BARIUM titanate, RARE earth oxides, DOMAIN walls (Ferromagnetism)

Abstract

The improper ferroelectric CsNbW2O9 has recently been highlighted as the first material outside the manganite family to exhibit a similar meandering, sixfold domain structure to that responsible for enhanced and diminished conduction at charged domain walls in the rare earth manganites. While there is no current evidence for variation in domain wall conduction relative to bulk in CsNbW2O9, the similarities in microstructure strongly suggest that charged domain walls are present in this material. Herein, we report a comprehensive study of the domain microstructure of CsNbW2O9 by both piezoresponse force microscopy and transmission electron microscopy to reveal that there are, in fact, clear distinctions in the domain structure of the two systems. Constraints arising from the crystal structure of CsNbW2O9, namely, the connectivity of the BO6 polyhedra and atomic displacements occurring purely along the c axis, mean that domain walls preferentially run parallel to the c direction (the polar axis of the material) and thus remain uncharged. The characteristic cloverleaf domain structure reminiscent of the manganites is still present; however, the structure meanders predominantly in the ab plane and, therefore, appears differently depending on the projection direction from which it is viewed. As a result of this microstructural constraint, charged domain walls are not prevalent in this material. [ABSTRACT FROM AUTHOR]

Published

2020