1 / 48

Tetravalent Ions Doped Lithium Niobate Crystals

Tetravalent Ions Doped Lithium Niobate Crystals. Yongfa Kong , Shiguo Liu, Shaolin Chen, and Jingjun Xu. School of Physics and TEDA Applied Physics School. Outline. 1. Introduction 2. Optical damage resistance 3. Photorefraction 4. Concluding remarks. 1. Introduction.

lilli
Download Presentation

Tetravalent Ions Doped Lithium Niobate Crystals

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Tetravalent Ions Doped Lithium Niobate Crystals Yongfa Kong, Shiguo Liu, Shaolin Chen, and Jingjun Xu School of Physics and TEDA Applied Physics School

  2. Outline 1. Introduction 2. Optical damage resistance 3. Photorefraction 4. Concluding remarks

  3. 1. Introduction • The topic of this workshop is on Optics and New materials. • Lithium niobate crystal is dull compared with the vast variability of today’s deliberately engineered materials. • Is there any news?

  4. Materials Update:Material of the month November 2002:Lithium niobate • In the field of nonlinear optics there have been many contenders for the title of all-star material of the world. • But for day-to-day applications, the most successful of these nonlinear materials is lithium niobate. • Indeed, because of its availability, widespread use and versatility, it has been dubbed by many as the “silicon of nonlinear optics”.

  5. Silicon of photonics • Lithium niobate (LiNbO3), also called the ‘silicon of photonics’, is indispensable in advanced photonics and nonlinear optics. M. Kösters1, et al., Nature Photonics 3, 510 (2009)

  6. Lithium niobate (LiNbO3, LN) • Multi-functions: • electro-optic, acousto-optic, elasto-optic, piezoelectric, pyroelectric, ferroelectric, nonlinear optic, etc. • Multi-applications: • Waveguides, modulators, isolators, frequency transformers, optical parametric oscillators, filters, sensors, holographic storage, etc. • Property controllability: • Good solubility to many dopants, • Properties change with different dopants and doping concentrations.

  7. “Optical silicon” New materials renew life for integrated opticsLawrence GasmanWDM Solutions, November, 2001 Material systems based on silica on silicon, gallium arsenide,lithium niobate, and indium phosphide are contenders for the role of "optical silicon."

  8. Workshop on Optics and New Materials II • The topics include metamaterials, plasmonics, optical lattice, photonic crystals, and novel quantum effects of light-matter interaction. • S. Zhu, et al., Quasi-phase-matched third-harmonic generation in a quasi- • periodic optical superlattice. Science 278, 843–846 (1997). • N. G. R. Broderick, et al., Hexagonally poled lithium niobate: a two- • dimensional nonlinear photonic crystal. Phys. Rev. Lett. 84, 4345–4348 (2000). • V. Ilchenko, et al., Nonlinear optics and crystalline whispering gallery mode • cavities. Phys. Rev. Lett. 92, 043903 (2004). • C. Canalias, et al., V. Mirrorlessoptical parametric oscillator. Nature Photon. • 1, 459–462 (2007). • A. Guarino, et al., Electro-optically tunable microringresonators in lithium • niobate. Nature Photon. 1, 407–410 (2007). • R. C. J. Hsu, et al., All-dielectric photonic-assistedradio front-end technology. • Nature Photon. 1, 535–538 (2007). • W. Yang, et al., Non-reciprocalultrafast laser writing. Nature Photon. 2, 99– • 104 (2008).

  9. Whathave been done on Lithium niobate crystal? In 1965, Ballman et al. firstly succeeded in growing lithium niobate single crystal: • SAW Filter: 4~5 inch single crystals; • Electro-optic modulator: 3~4 inch single crystals; • Photorefraction: Fe, Cu, Mn, or Ce doped crystals; • Optical damage resistance : Mg, Zn, In, or Sc doped crystals; • Property enhancement : nearly stoichiometric crystals; • Optical waveguide: H+, Ti; • QPM: PPLN, PPMgLN; • ……….

  10. Good enough? • Acoustic grade crystals: inhomogeneous stress, low electricity; • Optical grade crystals: graining stripes; • Photorefraction: long response time, low sensitivity; • Optical damage resistance: poor optical quality, only in visible range; • QPM:PPLN, low optical damage resistance, PPMgLN, hard to fabricate, poor thermal stability; • NS crystals: very difficult to grow, very poor optical quality; • Defect structures • Energy levels • Mechanism ……….

  11. What can tetravalent dopants do? • Optical damage resistance • Photorefraction • Domain engineering • Crystal growth • Micro-mechanism of some effects • and structural design

  12. 2. Optical damage resistance Optical damage • Light-induced optical damage, now also named as photorefraction, was discovered in LiNbO3 and LiTaO3 crystals. Photorefraction (PR) • Can be used in • holographic storage, • information processing, • light control of light. • low response speed, volatility. Optical damage • Hinders the applications: • frequency doublers, • optical parametric oscillators, • Q-switches, • optical waveguides. A. Ashkin, et al., Appl. Phys. Lett. 9, 72(1966)

  13. A solution: doping • 1980, Mg2+ ions, LN:Mg; “Star of China” • It promotes the practical applications of LN in nonlinear optics at high light intensities. • 1990, Zn2+ ions, LN:Zn; • 1992, Sc3+ ions, LN:Sc; • 1995, In3+ ions, LN:In. G. Zhong et al., J. Opt. Soc. Am. 70,631(1980). T. R. Volk et al., Opt. Lett.15, 996 (1990). J. K. Yamamoto et al., Appl. Phys. Lett.61, 2156 (1992). Y. Kong et al., Appl. Phys. Lett. 63, 280 (1995).

  14. The problems of doped LN • It is difficult to grow high optical quality crystals. • Large amounts of doping concentrations; (such as usually 5 mol% Mg for CLN) • Distribution coefficient far from 1.0; (such as 1.2 for Mg) • Some properties are still not satisfied: • Resistance not high enough, • Enhanced ultraviolet photorefraction (UVPR).

  15. HfO2 doped LiNbO3 (LN:Hf) E.P. Kokanyan et al., J. Appl. Phys. 92 1544 (2002); Appl. Phys. Lett. 48, 1980 (2004).

  16. Optical damage resistance of LN:Hf • LN:Hf4 is able to withstand a light density of 5×105 W/cm2 without noticeable beam smearing, • which is comparable to that observed in 6.5mol% MgO doped LN (LN:Mg6.5) crystal. (a)2 mol% Hf;(b) 4 mol% Hf;(c) 6 mol% Hf;(d) 6.5 mol% Mg The light intensity for (a) is 104 W/cm2 and 5×105 W/cm2 for (b), (c), and (d). S. Li et al., J. Phys.: Condens. Matter. 18, 3527(2006).

  17. ZrO2 doped LiNbO3 (LN:Zr) • As the doping concentration reaches 2.0 mol% ZrO2, LN:Zr crystals can withstand a light intensity as high as 2.0107 W/cm2. • At the same experimental conditions, the light intensity that 6.5 mol% Mg doped LN (LN:Mg6.5) can withstand is about 5.0105 W/cm2. (a) (b) (c) (d) (a), (b) and (c) LN:Zr1.7; (d) LN: Zr2. The light intensity for (a) is 1.3103 W/cm2, (b) 1.3104 W/cm2, (c) and (d) 2.0107 W/cm2. Y. Kong et al., Appl. Phys. Lett. 91, 081908 (2007).

  18. Light-induced changes of refractive indices • As the doping concentration of Zr above 2.0 mol%, the refractive index changes of LN:Zr crystals are one order of magnitude smaller than that of LN:Hf and LN:Mg. • Light-induced change of the refractive index in saturationas a function of dopants

  19. The distribution coefficient of Zr • The maximum value is 1.04 and the minimum value is 0.97. • Therefore, the distribution coefficient of Zr is much closer to one than that of Mg.

  20. SnO2 doped LiNbO3 (LN:Sn) Distortion of transmitted argon laser beam spots after 5 min of irradiation. (a)-(d) for Sn1:LN, Sn2:LN, Sn2.5:LN, and Sn5:LN, respectively. The light intensities are (a) 2.5×102 W/cm2, (b) 4.7×103 W/cm2, (c) 4.8×105 W/cm2, and (d) 5.4×105 W/cm2. L. Wang et al., Opt. Lett. 35, 883 (2010).

  21. The distribution coefficient of LN:Sn Dependence of the distribution coefficient of Sn4+ ions in Sn:LN crystals on the doping levels of SnO2.

  22. Ultraviolet photorefraction (UVPR) Enhancement of UVPR in LN:Mg J. Xu, et al., Opt. Lett. 25, 129(2000)

  23. Pulsed UV image amplification for programmable laser marking A laser at 355 nm, with 5 mJ, 10 ns pulse duration, a repetition rate of 20 Hz.

  24. The UVPR of LN:Zn and LN:In H. Qiao, et al., Phys. Rev. B 70, 094101(2004).

  25. The resistance of LN:Zr to UVPR Fig.1 The dependence of UV photorefractive diffraction efficiency and saturated refractive index change of LN:Zr on the doping concentration of Zr. • The open symbols show the data for LN:Mg5. Fig.2 Beam distortion of the transmitted UV light passing through LiNbO3 crystals (wavelength 351 nm, intensity 1.6×105 W/cm2). (a) PLN; (b) LN:Zr1; (c) LN:Zr2; (d) LN:Zr5. F. Liu, et al., Opt. Lett. 35, 10 (2010)

  26. The UVPR of LN:Hf Fig.1 Distortion of transmitted UV beam spots after irradiation of 5 min (wavelength 351nm, intensity 18.5 kW/cm2); a–e correspond to LN doped with 2, 2.5, 3, 4, and 6 mol.% Hf. W. Yan, et al., Opt. Lett. 35, 601 (2010)

  27. Comparison of LN:Mg, LN:Hf, LN:Zr and LN:Sn *6.5 mol% MgO; **5 mol% MgO in melt.

  28. 3. Photorefraction Fe2O3 doped LiNbO3 (LN:Fe) • By now, Fe2O3 doped LiNbO3 (LN:Fe) is one of the most excellent candidate materials for optical data storage due to its: • high diffraction efficiency, • high data storage density, • long storage lifetime. • The problems: • low response speed, • strong light-induced scattering, • volatility.

  29. A solution to increase the response speed • Co-doping with damage-resistant elements such as Mg, Zn, In and Sc, has been found to be a useful way to increase the response speed and resistance to scattering. • When the doping concentrations are above the threshold, Fe3+ ions and part of Fe2+ ions on Li sites will be repelled to Nb sites, • improves the response speed. • apparently decreases the diffraction efficiency. G. Zhang, Proc. SPIE2529, 14 (1995).

  30. HfO2 and Fe2O3 co-doped LiNbO3(LN:Fe,Hf) S. Li, et al., Appl. Phys. Lett. 89, 101126 (2006)

  31. ZrO2 and Fe2O3 co-doped LiNbO3(LN:Fe,Zr) Y. Kong et al., Appl. Phys. Lett. 92, 251107 (2008)

  32. The OH- absorption spectra of LN:Fe,Zr 3507 cm-1: Fe3+ in Nb-site LN:Fe,Zr: from top to bottom are for 1, 2, 3, 4, and 5 mol% Zr, respectively; 0.03 wt% Fe LN:Fe:Mg

  33. The UV-Visible spectra of LN:Fe,Zr and LN:Fe,Hf 400~700 nm:Fe2+Nb5+ intervalence transfer • Fe2+/3+ ions still remain at Li sites when the doping concentration of ZrO2 or HfO2 goes above its threshold value! LN:Fe, Zr: A, B, C, D, and E are for 1, 2, 3, 4, and 5 mol% Zr, and X and Y are for 2 and 5 mol% Hf, respectively; 0.03% Fe.

  34. Comparison of LN:Fe, LN:Fe,Mg, LN:Fe,Hf and LN:Fe,Zr S. Li, et al., Appl. Phys. Lett. 89, 101126 (2006) Y. Kong et al., Appl. Phys. Lett. 92, 251107 (2008)

  35. Nonvolatile holographic storage LiNbO3:Fe,Mn one-center two-center K. Buse, et al., Nature 393, 665 (1998)

  36. Energy level diagram of LiNbO3 Conduction band Conduction band The co-doping of Zr eliminates undesired intrinsic electron traps, which greatly enhances the charge transition speed for nonvolatile holographic storage 1.6 eV NbLi4+/5+ 2.5 eV 2.6 eV 2.6 eV 2.8 eV 2.8 eV NbLi4+/5+ NbNb4+/5+ EFermi EFermi Fe2+/3+ Fe2+/3+ Mn2+/3+ Mn2+/3+ CLN:Mn,Fe LN:Zr,Fe,Mn

  37. LiNbO3:Zr,Fe,Mn Y. Kong et al., Opt. Lett 34, 3896 (2009)

  38. Comparison of LN:Zr,Fe,Mn, LN:Mg,Fe,Mn, and LN:In,Fe,Mn

  39. LiNbO3:Zr,Cu,Ce The light intensity dependence of the measured light-induced scattering in the samples of triply doped LiNbO3 crystals. The lines are guides to the eyes. F. Liu et al., Opt. Express 18, 6333 (2010)

  40. The sensitivity of LiNbO3 co-doped with different ions for nonvolatile holographic storage

  41. 4. Concluding remarks • The above results indicate that tetravalent ions are excellent choice for the control of optical damage or photorefraction of LN. • These results also open a door for us to understand the micro-mechanism of optical damage resistance. • These results give us suitable choices for crystal design. The question remains: Why LN:Zr has such outstanding properties as compared with LN:Hf, LN:Sn, and LN:Mg?

  42. Silicon single crystal Fig. 2. Cross-sectional view of the defect-free, near-surface region of a silicon wafer. The lower portion of the figure shows silicon dioxide precipitates used for impurity gettering. Fig. 1. Range of electrical resistivities of pure and donor-doped silicon single crystals shown in comparison with metals and insulators. H. Queisser, et al., Science 281, 945 (1998)

  43. Optical fiber In 1966, Prof. Kao and Hockham proposed that when the loss of glass fiber was less than 20 dB/km it could be used as a conductor for optic communication, however at that time the loss of the best optical glass in the world was as large as 1000 dB/km. • In 1970,Corning Incorporated made optical fibers with loss of 20dB/km. • In 1974, the loss of optical fiber reduced to 2 dB/km as the purity of raw materials increased to 8N. • In 1976, the loss of optical fiber reduced to 0.5 dB/km as the concentration of OH in raw materials controlled in the order of ppm. • In 1980, the transport loss of optical fiber dropped to only 0.2 dB/km, which is closed to the theoretical value of 0.15dB/km.

  44. How about lithium niobate crystals? • Though lithium niobate has been dubbed as “optical silicon” or “photonic silicon”, compared with silicon single crystal and optical fiber, its research is rather preliminary. • We do not exactly know: • the defect structures, even the intrinsic defects, • the function of every dopant, • the relationship between defects and optical or photonic properties. • We are far from what we expect: • The control of defects; • The growth of high quality single crystals. • Our dream!

  45. Thank you for your attention!

More Related