Photon-induced electric field poling

In physics, photon-induced electric field poling is a phenomenon whereby a pattern of local electric field orientations can be encoded in a suitable ferroelectric material, such as perovskite. The resulting encoded material is conceptually similar to the pattern of magnetic field orientations within the magnetic domains of a ferromagnet, and thus may be considered as a possible technology for computer storage media. The encoded regions are optically active (have a varying index of refraction) and thus may be "read out" optically.

Encoding process

The encoding process proceeds by application of ultraviolet light tuned to the absorption band associated with the transition of electrons from the valence band to the conduction band. During UV application, an external electric field is used to modify the electric dipole moment of regions of the ferroelectric material that are exposed to UV light. By this process, a pattern of local electric field orientations can be encoded.

Technically, the encoding effect proceeds by the creation of a population inversion between the valence and conduction bands, with the resulting creation of plasmons. During this time, ferroelectric perovskite materials can be forced to change geometry by the application of an electric field. The encoded regions become optically active due to the Pockels effect.

Decoding process

The pattern of ferroelectric domain orientations can be read out optically. The refractive index of the ferroelectric material at wavelengths from near-infrared through to near-ultraviolet is affected by the electric field within the material. A changing pattern of electric field domains within a ferroelectric substrate results in different regions of the substrate having different refractive indices. Under these conditions, the substrate behaves as a diffraction grating, allowing the pattern of domains to be inferred from the interference pattern present in the transmitted readout beam.

See also

• Electro-optic effect
• Birefringence
• Holographic memory
• Magneto-optic effect

References

References discussing techniques described in this article

• Müller, Manfred; Soergel, Elisabeth; Buse, Karsten (2003). "Influence of ultraviolet illumination on the poling characteristics of lithium niobate crystals" (PDF). Applied Physics Letters. 83 (9). AIP Publishing: 1824–1826. Bibcode:2003ApPhL..83.1824M. doi:10.1063/1.1606504. ISSN 0003-6951. S2CID 118643463. Archived from the original (PDF) on 2011-07-16.
• Kapphan, S. E.; Kislova, I.; Wierschem, M.; Lindemann, T.; Gao, M.; Pankrath, R.; Vikhnin, V. S.; Kutsenko, A. B. (2003). "Light-Induced Polaronic Absorption at Low Temperature in Pure and (Fe, Ce, Cr) Doped Sr_xBa_1−xNb₂O₆ or Ba_1−xCa_xTiO₃ Crystals and Photodissociation of Vis Centers Into Small Polarons" (PDF). Radiation Effects and Defects in Solids. 158 (1–6). Informa UK Limited: 357–362. doi:10.1080/1042015021000052656. ISSN 1042-0150. S2CID 95403481. Archived from the original (PDF) on 2012-02-04.

References describing related techniques

• Grachev, Alexander I.; Kamshilin, Alexei A. (2005). "Electric polarization induced by optical orientation of dipolar centers in non-polar piezoelectrics". Optics Express. 13 (21). The Optical Society: 8565. Bibcode:2005OExpr..13.8565G. doi:10.1364/opex.13.008565. ISSN 1094-4087.
• Anna Fragemann (2005). Optical Parametric Amplification with Periodically Poled KTiOPO₄ (doctoral). Stockholm, Sweden: Department of Physics, Royal Institute of Technology.
• Sangalli, P.; Giulotto, E.; Rollandi, L.; Calvi, P.; Camagni, P.; Samoggia, G. (1998-03-15). "Photoinduced electronic transport in K_1−xLi_xTaO₃". Physical Review B. 57 (11). American Physical Society (APS): 6231–6234. Bibcode:1998PhRvB..57.6231S. doi:10.1103/physrevb.57.6231. ISSN 0163-1829.

Other articles about ferroelectric data storage

• "Tiny Bubbles in Nanofilms",
• Bo-Kuai Lai, Inna Ponomareva, Ivan Naumov, Igor Kornev, Huaxiang Fu, Laurent Bellaiche, and Greg Salamo, press release, University of Arkansas, 16 Mar. 2006