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Photostimulated BaSi2O5: Eu2+, Nd3+ Phosphor-in-glass Developed as Erasable-rewritable Optical Storage Medium

Apr 18, 2019

Upon irradiating by short-wavelength photons, the photostimulated luminescence materials can capture the created charged carriers in traps, and then release the stored carriers via long-wavelength light stimulation. To further develop this kind of optical storage materials, to improve storage density, enhance signal persistence, increase erasable stability and reduce the cost, are the key factors.

In the study published in Laser & Photonics Reviews, a research group led by Prof. WANG Yuansheng and Prof. LIN Hang from Fujian Institute of Research on the Structure of Matter (FJIRSM) of Chinese Academy of Sciences reported a novel multidimensional erasable optical storage material, i.e., BaSi2O5: Eu2+, Nd3+ phosphor-in-glass (PiG).

To show the application potential in optical storage, researchers encoded the graphic patterns, bar code, quick response code and binary data into BaSi2O5: Eu2+, Nd3+ PiG by ultraviolet light (350 nm) and decoded them by near-infrared light (808 nm).

The prepared BaSi2O5: Eu2+, Nd3+ PiG can achieve intensity-multiplexing by changing the power of the laser to expand the storage dimension.

Furthermore, the experimental results of a series of thermoluminescence spectrum revealed the existence of the narrowly-distributed deep traps (depth of 1.29 eV, full width at half maximum of 0.16 eV). This character resulted in the wonderful photostimulated luminescence performance and good signal persistence.

Thanks to the excellent chemical stability and ultraviolet resistance of the glass matrix, this material owns the advantages of stable optical signal, erasable writing, and long service life.

This study will promote the development of novel photostimulated luminescence material and their applications in optical storage.

Contact

WANG Yuansheng

Fujian Institute of Research on the Structure of Matter

E-mail:

A Photostimulated BaSi2O5:Eu2+,Nd3+ Phosphor‐in‐Glass for Erasable‐Rewritable Optical Storage Medium

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