Abstract

Spontaneous strain and spontaneous folding of thin nanoplatelets are known phenomena whose microscopic mechanisms are still debated. In this work, first-principles calculations are used to study the mechanical stresses that arise in Janus CdSe nanoplatelets and result in their spontaneous strain. Calculations reveal the existence of three microscopic mechanisms of this phenomenon. Two bulk mechanisms are associated with the inverse piezoelectric effect in an electric field created by the difference in electronegativities of ligands and by the depolarizing field resulting from the difference in the potential jumps in electrical double layers on the surfaces of nanoplatelets. These mechanisms account for 5–25% of the observed effect. The third mechanism is associated with the surface strain of nanoplatelets by bridging bonds, and its influence is predominant. It is shown that the latter mechanism causes spontaneous folding of thin CdSe nanoplatelets and, depending on the values of surface stresses and lateral orientation of nanoplatelets, can result in formation of their experimentally observed structures such as scrolls, spirals, and twisted ribbons.

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