Rotational-Mode-Enhanced Piezoelectricity in a Ferroelectric Double Helix

Abstract: Recent theoretical work has predicted the existence of a dipole spiral" structure in strained freestanding membranes, promising a route to giant electromechanical responses[\href{https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.133.046802}{PRL \textbf{133}, 046802 (2024)}]. However, its microscopic nature, energetic landscape, and electronic consequences remain largely unexplored. Here, using first-principles calculations on PbTiO$_3$ under biaxial tensile strain, we unveil a novel form of polar order: a chiral, non-collinear ferroelectric double helix. We find that the Pb- and Ti-cation sublattices form two distinct, intertwined helices, reminiscent of DNA. This intricate topology is stabilized by a collective helical twisting of the oxygen octahedral framework, which mediates an emergent electric Dzyaloshinskii-Moriya interaction.This unique structure, conceptualized as aself-Moir\'e" crystal, manifests two coupled functionalities. First, it possesses a rotational pseudo-zero-energy mode that underpins a giant piezoelectric response ($e_{33}\approx$16 C/m$^2$). Second, the spiral's long-period potential fundamentally reconstructs the electronic band structure, leading to an emergent multi-valley electronic topology at the valence band edge. Our work establishes a powerful, purely physical route to designing complex chiral order and provides a unified platform where structural topology, giant electromechanical coupling, and multi-valley electronics are intrinsically linked.