We present an inkjet-defined cholesteric liquid crystal (CLC) pixel architecture that enables frequency-addressable tristable optical memory for energy-efficient reflective modulation. Drop-on-demand printing forms individually programmable CLC droplets in a scalable, mask-free format, translating frequency-driven multistability into a manufacturable pixel platform. Each printed pixel can be electrically written into three optically distinct states: a transparent colored state, a colorless opaque concealment state, and a colored opaque memory state that remains stable after removal of the driving field. The tristability originates from frequency-selective competition between ion-mediated electrohydrodynamic convection at low frequency and dielectric realignment at high frequency. By encoding optical states through frequency programming rather than sustained bias, the device achieves true field-off retention without continuous power input. The printed arrays reach 63.5 dpi with uniform switching over areas up to 8.5 × 8.5 cm2, exhibit repeatable cycling without threshold drift, and show negligible thermal load during operation. By integrating structural coloration, transmittance modulation, and nonvolatile optical memory within a scalable inkjet process, this work establishes a practical pathway toward large-area smart windows, reflective displays, and programmable photonic surfaces.
Ma et al. (Wed,) studied this question.