Crystal polarity enhanced by interactions between antiparallel crystal dipoles

From zinc acetates dispersed within monolayers of poled polymer ferroelectric lamellar crystals, the growth of zinc oxide nanorods has been surprisingly identified subject to antiparallel match between crystal dipoles, unveiling a new type of non-contact epitaxial relationship therefore. The involved phase interactions between antiparallel crystal dipoles significantly enhance reversible piezoelectric strains of both interacting crystals, and the achieved piezoelectric constants of polymer ferroelectric crystals are increased by one order of magnitude. As two interacting crystals are further separated, achieved piezoelectricity of individual crystals declines accord-ingly, similar to the influences of noncovalent interactions between molecules. Upon guided crystal clustering, the available phase interactions significantly increase dielectric constants of prepared monolayers from 23 to more than 100. In addition to separation distance, the number and size of interacting crystals have been experimentally clarified critical also for reached levels of piezoelectric responses. Conceivably, unveiled phase interactions are dependent on the augmentation and enhancement of electric fields yielded by interacting crystal dipoles.

Automated summary

Zinc oxide nanorods are grown from zinc acetates dispersed within poled polymer ferroelectric lamellar crystals, revealing a new type of non-contact epitaxial relationship through antiparallel match between crystal dipoles. The phase interactions between antiparallel crystal dipoles significantly enhance reversible piezoelectric strains and increase the piezoelectric constants of polymer ferroelectric crystals by one order of magnitude. The presence and size of interacting crystals, along with the separation distance, play a critical role in the achieved levels of piezoelectric responses.