Negative piezoelectricity in quasi-two/one-dimensional ferroelectrics

TL;DR

This review explores the phenomenon of negative piezoelectricity in low-dimensional ferroelectrics, discussing its fundamental mechanisms, materials, theoretical predictions, experimental evidence, and future applications.

Contribution

It provides a comprehensive overview of negative piezoelectricity in quasi-two/one-dimensional ferroelectrics, highlighting diverse physical mechanisms and recent experimental discoveries.

Findings

Negative piezoelectricity observed in various layered ferroelectrics.

Multiple physical mechanisms can contribute to negative piezoelectricity.

Potential applications in nano-devices and future research directions.

Abstract

In recent years, the investigation of low-dimensional ferroelectrics has attracted great attention for their promising applications in nano devices. Piezoelectricity is one of the most core properties of ferroelectric materials, which plays the essential role in micro-electromechanical systems. Very recently, the anomalous negative piezoelectricity has been predicted/discovered in many quasi-two-dimensional layered ferroelectric materials. In this Topical Review, we will briefly introduce on the negative piezoelectricity in quasi-two/one-dimensional ferroelectrics, including its fundamental concept, typical materials, theoretical predictions, as well as experimental phenomena. The underlying physical mechanisms for negative piezoelectricity are divergent and varying from case by case, which can be categorized into four types. First, the soft van der Waals layer is responsible for the volume shrinking upon pressure while the electric dipoles is from non van der Waals layer. Second, the noncollinearity of local dipoles creates a ferrielectricity, which leads to orthogonal ferroelectric and antiferroelectric axes. Third, the electric dipoles come from interlayer/interchain couplings, which can be enhanced during the volume shrinking. Fourth, the special buckling structure contributes to local dipoles, which can be enhanced upon pressure. In real materials, more than one mechanism may work together. Finally, the future directions of negative piezoelectricity and their potential applications are outlooked.