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A dual-frequency photonic crystal nanocolloid with hue- and brightness-tunable structural colors

Tian‐Zi Shen, Kurugamage Nuwan Asela Perera, Aurangzeb Rashid Masud, P. A. N. S. Priyadharshana, Jooyoung Park, Qiong‐Hua Wang, Seung‐Ho Hong, Jang‐Kun Song

2023Cell Reports Physical Science15 citationsDOIOpen Access PDF

Abstract

Self-assembled lamellar nanocolloids of two-dimensional (2D) nanosheets can provide new possibilities for tunable photonic crystalline devices based on their vivid structural color and reconfigurability. However, this remains a challenge because of the veiled dynamic behavior of 2D nanocolloids under electric fields and the lack of feasible manipulation methods. Here, we demonstrate a full-color tunable polyoxyalkyleneamine-tethered α-TiP nanocolloid possessing the ability to tune hue and brightness by harnessing field-induced phase transition phenomena, in which the intrinsic lamellar phase can transition to an optically anti-nematic phase via an isotropic phase at high-frequency fields and vice versa at low-frequency fields. This unique switching behavior is attributed to the formation of a dynamic polydomain structure characterized by stable intradomain lamellar ordering and reconfigurable interdomain ordering. This causes a clear discrepancy between optical observations and X-ray scattering measurements. By exploiting these, a switchable and multistable photonic crystalline device is successfully demonstrated.

Topics & Concepts

Lamellar structureStructural colorationMaterials scienceReconfigurabilityLiquid crystalBrightnessPhase (matter)PhotonicsOptoelectronicsHueOpticsPhotonic crystalPhase transitionIsotropyCondensed matter physicsPhysicsComputer scienceTelecommunicationsComposite materialQuantum mechanicsPhotonic Crystals and ApplicationsQuantum Dots Synthesis And PropertiesLiquid Crystal Research Advancements
A dual-frequency photonic crystal nanocolloid with hue- and brightness-tunable structural colors | Litcius