Unlocking the key role of electric field stimulus in ferroelectric photochromic phosphor for partitioned optical storage and encrypted transmission

Ferroelectric photochromic phosphors (FPPs) are regarded as one of the most promising information storage media. Recently, rapid advancement has been achieved, however, the coupling mechanism between the inherent ferroelectric and photochromic (PC)/up-conversion luminescence (UCL) effect remains ambiguous. Here, the key role of the electric field on the PC/UCL performances in a new Ho³⁺/Yb³⁺ co-doped CaBi₈Ti₇O₂₇ FPPs was unlocked. The PC/UCL performances can be delicately tuned by the external electric field. Compared to the absence of the electric field or weak electric field related parameters (electric field strength, temperature, and time), strong electric field related parameters can induce greater PC/UCL modulation contrasts. This phenomenon can be attributed to the built-in electric field (E_int) generated by the combined actions of domain reorientation and charge accumulation, which effectively drives the separation of electrons and holes and promotes the formation of color centers. Based on precise control of PC effect and UCL performance by electric field, a coding disk designed with this material can achieve information partitioned storage and encrypted transmission. This work provides insights for the development and design of innovative multifunctional optical storage devices.