Your search keyword '"E. Stylianidis"' showing total 2 results

1. Mimicking Antiferroelectrics with Ferroelectric Superlattices.

Author

Yin C, Li Y, Zatterin E, Rusu D, Stylianidis E, Hadjimichael M, Aramberri H, Iñiguez-González J, Conroy M, and Zubko P

Abstract

Antiferroelectric oxides are promising materials for applications in high-density energy storage, solid-state cooling, and negative capacitance devices. However, the range of oxide antiferroelectrics available today is rather limited. In this work, it is demonstrated that antiferroelectric properties can be electrostatically engineered in artificially layered ferroelectric superlattices. Using a combination of synchrotron X-ray nanodiffraction, scanning transmission electron microscopy, macroscopic electrical measurements, and lateral and vertical piezoresponse force microscopy in parallel-plate capacitor geometry, a highly reversible field-induced transition is observed from a stable in-plane polarized state to a state with in-plane and out-of-plane polarized nanodomains that mimics, at the domain level, the nonpolar to polar transition of traditional antiferroelectrics, with corresponding polarization-voltage double hysteresis and comparable energy storage capacity. Furthermore, it is found that such superlattices exhibit large out-of-plane dielectric responses without involving flux-closure domain dynamics. These results demonstrate that electrostatic and strain engineering in artificially layered materials offers a promising route for the creation of synthetic antiferroelectrics., (© 2024 The Author(s). Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

2. Synthesis of Black Phosphorene Quantum Dots from Red Phosphorus.

Author

Shutt RRC, Ramireddy T, Stylianidis E, Di Mino C, Ingle RA, Ing G, Wibowo AA, Nguyen HT, Howard CA, Glushenkov AM, Stewart A, and Clancy AJ

Abstract

Black phosphorene quantum dots (BPQDs) are most commonly derived from high-cost black phosphorus, while previous syntheses from the low-cost red phosphorus (P red ) allotrope are highly oxidised. Herein, we present an intrinsically scalable method to produce high quality BPQDs, by first ball-milling P red to create nanocrystalline P black and subsequent reductive etching using lithium electride solvated in liquid ammonia. The resultant ~25 nm BPQDs are crystalline with low oxygen content, and spontaneously soluble as individualized monolayers in tertiary amide solvents, as directly imaged by liquid-phase transmission electron microscopy. This new method presents a scalable route to producing quantities of high quality BPQDs for academic and industrial applications., (© 2023 The Authors. Chemistry - A European Journal published by Wiley-VCH GmbH.)

Published

2023