Indirect evidence of Bi³⁺ valence change and dual role of Bi³⁺ in trapping electrons and holes for multimode X-ray imaging, anti-counterfeiting, and non-real-time force sensing

Abstract

Discovering bismuth based smart materials that can respond to thermal, mechanical, and wide range X-ray to infrared photon excitation remains a challenge. Such materials have various uses like in advanced information encryption. In this work, valence state change between Bi²⁺, Bi³⁺, and Bi⁴⁺, and the dual role of Bi³⁺ in trapping electrons and holes have been studied in Bi³⁺ or/and Ln³⁺ (Ln=Tb or Pr) doped LiScGeO₄ family of compounds by vacuum referred binding energy (VRBE) diagram construction, thermoluminescence, and spectroscopy. Electron release from Bi²⁺ has been evidenced. It can be used to experimentally determine the VRBE in the Bi^{2+ 2}P_1/2 ground state and to realize Bi³⁺ negative quenching luminescence. Particularly, a new force induced charge carrier storage phenomenon has been discovered for non-real-time force recording. Wide range of emission tailorable afterglow, unique Bi³⁺ ultraviolet-A, white, and infrared afterglow have been demonstrated by using Bi³⁺ as a hole trapping and recombination center and using energy transfer processes from Bi³⁺ to Tb³⁺, Pr³⁺, Dy³⁺, or Cr³⁺. Proof-of-concept advanced anti-counterfeiting, information encryption, and X-ray imaging will be demonstrated. This work not only develops smart storage phosphors, but more importantly unravels the valence change between Bi²⁺, Bi³⁺, or Bi⁴⁺ and how it can affect the trapping and release of charge carriers with thermal, optical, or mechanical excitation. This work therefore can promote the discovery and development of Bi³⁺ based smart materials for various applications.