Non-volatile holographic storage in doubly doped lithium niobate crystals

Photorefractive materials are being widely investigated for applications in holographic data storage. Inhomogeneous illumination of these materials with an optical interference pattern redistributes charge, builds up internal electric fields and so changes the refractive index. Subsequent homogeneous illumination results in light diffraction and reconstructs the information encoded in the original interference pattern. A range of inorganic and organic photorefractive materials are known, in which thousands of holograms of high fidelity can be efficiently stored, reconstructed and erased. But there remains a problem with volatility: the read-out process usually erases the stored information and amplifies the scattered light. Several techniques for ‘fixing’ holograms have been developed, but they have practical disadvantages and only laboratory demonstrators have been built. Here we describe a resolution to the problem of volatility that should lead to the realization of a more practical system. We use crystals of lithium niobate — available both in large size and with excellent homogeneity — that have been doped with two different deep electron traps (iron and manganese). Illumination of the crystals with incoherent ultraviolet light during the recording process permits the storage of data (a red-light interference pattern) that can be subsequently read, in the absence of ultraviolet light, without erasure. Our crystals show up to 32 per cent diffraction efficiency, rapid optical erasure of the stored data is possible using ultraviolet light, and light scattering is effectively prevented.

[1]  B. Derjaguin,et al.  Theory of the stability of strongly charged lyophobic sols and of the adhesion of strongly charged particles in solutions of electrolytes , 1993 .

[2]  J. J. Amodei,et al.  HOLOGRAPHIC PATTERN FIXING IN ELECTRO‐OPTIC CRYSTALS , 1971 .

[3]  F. Micheron,et al.  Electrical Control of Fixation and Erasure of Holographic Patterns in Ferroelectric Materials , 1972 .

[4]  W. Phillips,et al.  Hologram storage in photochromic LiNbO3 , 1974 .

[5]  Alastair M. Glass,et al.  Multiphoton photorefractive processes for optical storage in LiNbO3 , 1974 .

[6]  B. Dischler,et al.  Photorefractive centers in LiNbO3, studied by optical-, Mössbauer- and EPR-methods , 1977 .

[7]  R. Hastings On the crystallization of macroionic solutions , 1978 .

[8]  I. Sogami Effective potential between charged spherical particles in dilute suspension , 1983 .

[9]  T. Okubo,et al.  Ordered structure in dilute solutions of highly charged polymer lattices as studied by microscopy. I. Interparticle distance as a function of latex concentration , 1983 .

[10]  Norio Ise,et al.  On the electrostatic interaction in macroionic solutions , 1984 .

[11]  R. Orlowski,et al.  Photorefractive effects in LiNbO3:Cr induced by two‐step excitation , 1985 .

[12]  H. C. Külich A new approach to read volume holograms at different wavelengths , 1987 .

[13]  Ortwin F. Schirmer,et al.  Energy Levels Of Several 3D Impurities And EPR of Ti3+ in LiNbO3 , 1989, Other Conferences.

[14]  Karsten Buse,et al.  Activation of BaTiO3 for infrared holographic recording , 1991 .

[15]  N. Peyghambarian,et al.  A photorefractive polymer with high optical gain and diffraction efficiency near 100% , 1994, Nature.

[16]  Grier,et al.  Microscopic measurement of the pair interaction potential of charge-stabilized colloid. , 1994, Physical review letters.

[17]  Fraden,et al.  Attractive potential between confined colloids at low ionic strength. , 1994, Physical review letters.

[18]  P B Bennett,et al.  The physiology of decompression illness. , 1995, Scientific American.

[19]  Carbajal-Tinoco,et al.  Static properties of confined colloidal suspensions. , 1996, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[20]  D. Grier,et al.  Methods of Digital Video Microscopy for Colloidal Studies , 1996 .

[21]  L Hesselink,et al.  Digital holographic storage system incorporating thermal fixing in lithium niobate. , 1996, Optics letters.

[22]  D Psaltis,et al.  System metric for holographic memory systems. , 1996, Optics letters.

[23]  D. Grier,et al.  When Like Charges Attract: The Effects of Geometrical Confinement on Long-Range Colloidal Interactions. , 1996, Physical review letters.

[24]  Demetri Psaltis Holographic memories , 1996, International Commission for Optics.

[25]  Wasan,et al.  Attractive Interaction between Similarly Charged Colloidal Particles , 1996, Journal of colloid and interface science.

[26]  Bowen,et al.  Adaptive Finite-Element Solution of the Nonlinear Poisson-Boltzmann Equation: A Charged Spherical Particle at Various Distances from a Charged Cylindrical Pore in a Charged Planar Surface , 1997, Journal of colloid and interface science.

[27]  D Lande,et al.  Digital holographic storage system incorporating optical fixing. , 1997, Optics letters.

[28]  Jean-Pierre Hansen,et al.  VAN DER WAALS-LIKE INSTABILITY IN SUSPENSIONS OF MUTUALLY REPELLING CHARGED COLLOIDS , 1997 .

[29]  R R Neurgaonkar,et al.  Intensity dependence and white-light gating of two-color photorefractive gratings in LiNbO(3). , 1997, Optics letters.

[30]  D Psaltis,et al.  Electrical fixing of 1000 angle-multiplexed holograms in SBN:75. , 1997, Optics letters.

[31]  David G. Grier,et al.  Optical tweezers in colloid and interface science , 1997 .

[32]  B. Tata,et al.  AMORPHOUS CLUSTERING IN HIGHLY CHARGED DILUTE POLY(CHLOROSTYRENE-STYRENE SULFONATE) COLLOIDS , 1997 .

[33]  D Psaltis,et al.  Storage of 1000 holograms with use of a dual-wavelength method. , 1997, Applied optics.

[34]  David G. Grier,et al.  Like-charge attractions in metastable colloidal crystallites , 1997, Nature.