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Strontium titanate

December 07, 2023

Strontium titanate is an oxide of strontium and titanium with the chemical formula SrTiO3. At room temperature, it is a centrosymmetric paraelectric material with a perovskite structure. At low temperatures it approaches a ferroelectric phase transition with a very large dielectric constant ~104 but remains paraelectric down to the lowest temperatures measured as a result of quantum fluctuations, making it a quantum paraelectric.[1] It was long thought to be a wholly artificial material, until 1982 when its natural counterpart—discovered in Siberia and named tausonite—was recognised by the IMA. Tausonite remains an extremely rare mineral in nature, occurring as very tiny crystals. Its most important application has been in its synthesized form wherein it is occasionally encountered as a diamond simulant, in precision optics, in varistors, and in advanced ceramics.

Strontium titanate
Names
Other names
Strontium titanium oxide

Tausonite

STO
Identifiers
  • 12060-59-2 Y
3D model (JSmol)
  • Interactive image
  • Interactive image
ChemSpider
  • 74801 Y
ECHA InfoCard 100.031.846
EC Number
  • 235-044-1
MeSH Strontium+titanium+oxide
  • 82899
UNII
  • OLH4I98373 Y
  • DTXSID70893688
  • InChI=1S/3O.Sr.Ti/q;2*-1;+2; Y
    Key: VEALVRVVWBQVSL-UHFFFAOYSA-N Y
  • InChI=1/3O.Sr.Ti/q;2*-1;+2;/rO3Ti.Sr/c1-4(2)3;/q-2;+2
    Key: VEALVRVVWBQVSL-VUHNDFTMAE
  • [Sr++].[O-][Ti]([O-])=O
  • [Sr+2].[O-][Ti]([O-])=O
Properties
SrTiO
3
Molar mass 183.49 g/mol
Appearance White, opaque crystals
Density 5.11 g/cm3
Melting point 2,080 °C (3,780 °F; 2,350 K)
insoluble
2.394
Structure
Cubic Perovskite
Pm3m, No. 221
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Y verify (what is YN ?)

The name tausonite was given in honour of Lev Vladimirovich Tauson (1917–1989), a Russian geochemist. Disused trade names for the synthetic product include strontium mesotitanate, Diagem, and Marvelite. This product is currently being marketed for its use in jewelry under the name Fabulite.[2] Other than its type locality of the Murun Massif in the Sakha Republic, natural tausonite is also found in Cerro Sarambi, Concepción department, Paraguay; and along the Kotaki River of Honshū, Japan.[3][4]

Properties edit

 
Atomic resolution image of SrTiO3 acquired using a Scanning Transmission Electron Microscope (STEM) and a high angle annular dark field (HAADF) detector. Brighter spots are columns of atoms containing Sr, and darker spots contain Ti. Columns containing only O atoms are not visible.
 
Structure of SrTiO3. The red spheres are oxygens, blue are Ti4+ cations, and the green ones are Sr2+.

SrTiO3 has an indirect band gap of 3.25 eV and a direct gap of 3.75 eV [5] in the typical range of semiconductors. Synthetic strontium titanate has a very large dielectric constant (300) at room temperature and low electric field. It has a specific resistivity of over 109 Ω-cm for very pure crystals.[6] It is also used in high-voltage capacitors. Introducing mobile charge carriers by doping leads to Fermi-liquid metallic behavior already at very low charge carrier densities.[7] At high electron densities strontium titanate becomes superconducting below 0.35 K and was the first insulator and oxide discovered to be superconductive.[8]

Strontium titanate is both much denser (specific gravity 4.88 for natural, 5.13 for synthetic) and much softer (Mohs hardness 5.5 for synthetic, 6–6.5 for natural) than diamond. Its crystal system is cubic and its refractive index (2.410—as measured by sodium light, 589.3 nm) is nearly identical to that of diamond (at 2.417), but the dispersion (the optical property responsible for the "fire" of the cut gemstones) of strontium titanate is 4.3x that of diamond, at 0.190 (B–G interval). This results in a shocking display of fire compared to diamond and diamond simulants such as YAG, GAG, GGG, Cubic Zirconia, and Moissanite.[3][4]

Synthetics are usually transparent and colourless, but can be doped with certain rare earth or transition metals to give reds, yellows, browns, and blues. Natural tausonite is usually translucent to opaque, in shades of reddish brown, dark red, or grey. Both have an adamantine (diamond-like) lustre. Strontium titanate is considered extremely brittle with a conchoidal fracture; natural material is cubic or octahedral in habit and streaks brown. Through a hand-held (direct vision) spectroscope, doped synthetics will exhibit a rich absorption spectrum typical of doped stones. Synthetic material has a melting point of ca. 2080 °C (3776 °F) and is readily attacked by hydrofluoric acid.[3][4] Under extremely low oxygen partial pressure, strontium titanate decomposes via incongruent sublimation of strontium well below the melting temperature.[9]

At temperatures lower than 105 K, its cubic structure transforms to tetragonal.[10] Its monocrystals can be used as optical windows and high-quality sputter deposition targets.

 
Strontium titanate single crystal substrates (5x5x0.5mm). The transparent substrate (left) is pure SrTiO3 and the black substrate is doped with 0.5% (weight) of niobium

SrTiO3 is an excellent substrate for epitaxial growth of high-temperature superconductors and many oxide-based thin films. It is particularly well known as the substrate for the growth of the lanthanum aluminate-strontium titanate interface. Doping strontium titanate with niobium makes it electrically conductive, being one of the only conductive commercially available single crystal substrates for the growth of perovskite oxides. Its bulk lattice parameter of 3.905Å makes it suitable as the substrate for the growth of many other oxides, including the rare-earth manganites, titanates, lanthanum aluminate (LaAlO3), strontium ruthenate (SrRuO3) and many others. Oxygen vacancies are fairly common in SrTiO3 crystals and thin films. Oxygen vacancies induce free electrons in the conduction band of the material, making it more conductive and opaque. These vacancies can be caused by exposure to reducing conditions, such as high vacuum at elevated temperatures.

High-quality, epitaxial SrTiO3 layers can also be grown on silicon without forming silicon dioxide, thereby making SrTiO3 an alternative gate dielectric material. This also enables the integration of other thin film perovskite oxides onto silicon.[11]

SrTiO3 has been shown to possess persistent photoconductivity where exposing the crystal to light will increase its electrical conductivity by over 2 orders of magnitude. After the light is turned off, the enhanced conductivity persists for several days, with negligible decay.[12][13]

Due to the significant ionic and electronic conduction of SrTiO3, it is potent to be used as the mixed conductor.[14]

Synthesis edit

 
A plate cut out of synthetic SrTiO3 crystal

Synthetic strontium titanate was one of several titanates patented during the late 1940s and early 1950s; other titanates included barium titanate and calcium titanate. Research was conducted primarily at the National Lead Company (later renamed NL Industries) in the United States, by Leon Merker and Langtry E. Lynd. Merker and Lynd first patented the growth process on February 10, 1953; a number of refinements were subsequently patented over the next four years, such as modifications to the feed powder and additions of colouring dopants.

A modification to the basic Verneuil process (also known as flame-fusion) is the favoured method of growth. An inverted oxy-hydrogen blowpipe is used, with feed powder mixed with oxygen carefully fed through the blowpipe in the typical fashion, but with the addition of a third pipe to deliver oxygen—creating a tricone burner. The extra oxygen is required for successful formation of strontium titanate, which would otherwise fail to oxidize completely due to the titanium component. The ratio is ca. 1.5 volumes of hydrogen for each volume of oxygen. The highly purified feed powder is derived by first producing titanyl double oxalate salt (SrTiO(C2O4)2 · 2 H2O) by reacting strontium chloride (SrCl2) and oxalic acid ((COOH)2 · 2 H2O) with titanium tetrachloride (TiCl4). The salt is washed to completely eliminate chloride, heated to 1000 °C in order to produce a free-flowing granular powder of the required composition, and is then ground and sieved to ensure all particles are between 0.2–0.5 micrometres in size.[15]

The feed powder falls through the oxyhydrogen flame, melts, and lands on a rotating and slowly descending pedestal below. The height of the pedestal is constantly adjusted to keep its top at the optimal position below the flame, and over a number of hours the molten powder cools and crystallises to form a single pedunculated pear or boule crystal. This boule is usually no larger than 2.5 centimetres in diameter and 10 centimetres long; it is an opaque black to begin with, requiring further annealing in an oxidizing atmosphere in order to make the crystal colourless and to relieve strain. This is done at over 1000 °C for 12 hours.[15]

Thin films of SrTiO3 can be grown epitaxially by various methods, including pulsed laser deposition, molecular beam epitaxy, RF sputtering and atomic layer deposition. As in most thin films, different growth methods can result in significantly different defect and impurity densities and crystalline quality, resulting in a large variation of the electronic and optical properties.

Use as a diamond simulant edit

Its cubic structure and high dispersion once made synthetic strontium titanate a prime candidate for simulating diamond. Beginning c. 1955, large quantities of strontium titanate were manufactured for this sole purpose. Strontium titanate was in competition with synthetic rutile ("titania") at the time, and had the advantage of lacking the unfortunate yellow tinge and strong birefringence inherent to the latter material. While it was softer, it was significantly closer to diamond in likeness. Eventually, however, both would fall into disuse, being eclipsed by the creation of "better" simulants: first by yttrium aluminium garnet (YAG) and followed shortly after by gadolinium gallium garnet (GGG); and finally by the (to date) ultimate simulant in terms of diamond-likeness and cost-effectiveness, cubic zirconia.[16]

Despite being outmoded, strontium titanate is still manufactured and periodically encountered in jewellery. It is one of the most costly of diamond simulants, and due to its rarity collectors may pay a premium for large i.e. >2 carat (400 mg) specimens. As a diamond simulant, strontium titanate is most deceptive when mingled with melée i.e. <0.20 carat (40 mg) stones and when it is used as the base material for a composite or doublet stone (with, e.g., synthetic corundum as the crown or top of the stone). Under the microscope, gemmologists distinguish strontium titanate from diamond by the former's softness—manifested by surface abrasions—and excess dispersion (to the trained eye), and occasional gas bubbles which are remnants of synthesis. Doublets can be detected by a join line at the girdle ("waist" of the stone) and flattened air bubbles or glue visible within the stone at the point of bonding.[17][18][19]

Use in radioisotope thermoelectric generators edit

Due to its high melting point and insolubility in water, strontium titanate has been used as a strontium-90-containing material in radioisotope thermoelectric generators (RTGs), such as the US Sentinel and Soviet Beta-M series.[20][21] As strontium-90 has a high fission product yield and is easily extracted from spent nuclear fuel, Sr-90 based RTGs can in principle be produced cheaper than those based on plutonium-238 or other radionuclides which have to be produced in dedicated facilities. However, due to the lower power density (~0.45W thermal per gram of Strontium-90-Titanate) and half life, space based applications, which put a particular premium on low weight, high reliability and longevity prefer Plutonium-238. Terrestrial off-grid applications of RTGs meanwhile have been largely phased out due to concern over orphan sources and the decreasing price and increasing availability of solar panels, small wind turbines, chemical battery storage and other off-grid power solutions.

Use in solid oxide fuel cells edit

Strontium titanate's mixed conductivity has attracted attention for use in solid oxide fuel cells (SOFCs). It demonstrates both electronic and ionic conductivity which is useful for SOFC electrodes because there is an exchange of gas and oxygen ions in the material and electrons on both sides of the cell.

  (anode)
  (cathode)

Strontium titanate is doped with different materials for use on different sides of a fuel cell. On the fuel side (anode), where the first reaction occurs, it is often doped with lanthanum to form lanthanum-doped strontium titanate (LST). In this case, the A-site, or position in the unit cell where strontium usually sits, is sometimes filled by lanthanum instead, this causes the material to exhibit n-type semiconductor properties, including electronic conductivity. It also shows oxygen ion conduction due to the perovskite structure tolerance for oxygen vacancies. This material has a thermal coefficient of expansion similar to that of the common electrolyte yttria-stabilized zirconia (YSZ), chemical stability during the reactions which occur at fuel cell electrodes, and electronic conductivity of up to 360 S/cm under SOFC operating conditions.[22] Another key advantage of these LST is that it shows a resistance to sulfur poisoning, which is an issue with the currently used nickel - ceramic (cermet) anodes.[23]

Another related compound is strontium titanium ferrite (STF) which is used as a cathode (oxygen-side) material in SOFCs. This material also shows mixed ionic and electronic conductivity which is important as it means the reduction reaction which happens at the cathode can occur over a wider area.[24] Building on this material by adding cobalt on the B-site (replacing titanium) as well as iron, we have the material STFC, or cobalt-substituted STF, which shows remarkable stability as a cathode material as well as lower polarization resistance than other common cathode materials such as lanthanum strontium cobalt ferrite. These cathodes also have the advantage of not containing rare earth metals which make them cheaper than many of the alternatives.[25]

See also edit

References edit

  1. ^ K. A. Muller & H. Burkard (1979). "SrTiO3: An intrinsic quantum paraelectric below 4 K". Phys. Rev. B. 19 (7): 3593–3602. Bibcode:1979PhRvB..19.3593M. doi:10.1103/PhysRevB.19.3593.
  2. ^ Mottana, Annibale (March 1986). "Una brillante sintesi". Scienza e Dossier (in Italian). Giunti. 1 (1): 9.
  3. ^ a b c "Tausonite". Webmineral. Retrieved 2009-06-06.
  4. ^ a b c "Tausonite". Mindat. Retrieved 2009-06-06.
  5. ^ K. van Benthem, C. Elsässer and R. H. French (2001). "Bulk electronic structure of SrTiO3: Experiment and theory". Journal of Applied Physics. 90 (12): 6156. Bibcode:2001JAP....90.6156V. doi:10.1063/1.1415766. S2CID 54065614.
  6. ^ . ESPI Metals. ESPICorp. Archived from the original on 2015-09-24.
  7. ^ Xiao Lin, Benoît Fauqué, Kamran Behnia (2015). "Scalable T2 resistivity in a small single-component Fermi surface". Science. 349 (6251): 945–8. arXiv:1508.07812. Bibcode:2015Sci...349..945L. doi:10.1126/science.aaa8655. PMID 26315430. S2CID 148360.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  8. ^ Koonce, C. S.; Cohen, Marvin L. (1967). "Superconducting Transition Temperatures of Semiconducting SrTiO3". Phys. Rev. 163 (2): 380. Bibcode:1967PhRv..163..380K. doi:10.1103/PhysRev.163.380.
  9. ^ C. Rodenbücher; P. Meuffels; W. Speier; M. Ermrich; D. Wrana; F. Krok; K. Szot (2017). "Stability and Decomposition of Perovskite-Type Titanates upon High-Temperature Reduction". Phys. Status Solidi RRL. 11 (9): 1700222. Bibcode:2017PSSRR..1100222R. doi:10.1002/pssr.201700222. S2CID 102882984.
  10. ^ L. Rimai & G. A. deMars (1962). "Electron Paramagnetic Resonance of Trivalent Gadolinium Ions in Strontium and Barium Titanates". Phys. Rev. 127 (3): 702. Bibcode:1962PhRv..127..702R. doi:10.1103/PhysRev.127.702.
  11. ^ R. A. McKee; F. J. Walker & M. F. Chisholm (1998). "Crystalline Oxides on Silicon: The First Five Monolayers". Phys. Rev. Lett. 81 (14): 3014. Bibcode:1998PhRvL..81.3014M. doi:10.1103/PhysRevLett.81.3014.
  12. ^ Tarun, Marianne C.; Selim, Farida A.; McCluskey, Matthew D. (2013). "Persistent Photoconductivity in Strontium Titanate". Physical Review Letters. Department of Physics and Astronomy, Washington State University, Pullman, Washington. 111 (18): 187403. Bibcode:2013PhRvL.111r7403T. doi:10.1103/PhysRevLett.111.187403. PMID 24237562. Retrieved 2013-11-18.
  13. ^ "Light Exposure Increases Crystal's Electrical Conductivity 400-fold [VIDEO]". Nature World News. Retrieved 2013-11-18.
  14. ^ "Mixed conductors". Max Planck institute for solid state research. Retrieved 16 September 2016.
  15. ^ a b H. J. Scheel & P. Capper (2008). Crystal growth technology: from fundamentals and simulation to large-scale production. Wiley-VCH. p. 431. ISBN 978-3-527-31762-2.
  16. ^ R. W. Hesse (2007). Jewelrymaking through history: an encyclopedia. Greenwood Publishing Group. p. 73. ISBN 978-0-313-33507-5.
  17. ^ Nassau, K. (1980). Gems made by man. Santa Monica, California: Gemological Institute of America. pp. 214–221. ISBN 0-87311-016-1.
  18. ^ O'Donoghue, M. (2002). Synthetic, imitation & treated gemstones. Great Britain: Elsevier Butterworth-Heinemann. pp. 34, 65. ISBN 0-7506-3173-2.
  19. ^ Read, P. G. (1999). Gemmology, second edition. Great Britain: Butterworth-Heinemann. pp. 173, 176, 177, 293. ISBN 0-7506-4411-7.
  20. ^ "Power Sources for Remote Arctic Applications" (PDF). Washington, DC: U.S. Congress, Office of Technology Assessment. June 1994. OTA-BP-ETI-129.
  21. ^ Standring, WJF; Selnæs, ØG; Sneve, M; Finne, IE; Hosseini, A; Amundsen, I; Strand, P (2005), (PDF), Østerås: Norwegian Radiation Protection Authority, archived from the original (PDF) on 2016-03-03, retrieved 2013-12-04
  22. ^ Marina, O (2002). "Thermal, electrical, and electrocatalytical properties of lanthanum-doped strontium titanate". Solid State Ionics. 149 (1–2): 21–28. doi:10.1016/S0167-2738(02)00140-6.
  23. ^ Gong, Mingyang; Liu, Xingbo; Trembly, Jason; Johnson, Christopher (2007). "Sulfur-tolerant anode materials for solid oxide fuel cell application". Journal of Power Sources. 168 (2): 289–298. Bibcode:2007JPS...168..289G. doi:10.1016/j.jpowsour.2007.03.026.
  24. ^ Jung, WooChul; Tuller, Harry L. (2009). "Impedance study of SrTi1−xFexO3−δ (x=0.05 to 0.80) mixed ionic-electronic conducting model cathode". Solid State Ionics. 180 (11–13): 843–847. doi:10.1016/j.ssi.2009.02.008.
  25. ^ Zhang, Shan-Lin; Wang, Hongqian; Lu, Matthew Y.; Zhang, Ai-Ping; Mogni, Liliana V.; Liu, Qinyuan; Li, Cheng-Xin; Li, Chang-Jiu; Barnett, Scott A. (2018). "Cobalt-substituted SrTi 0.3 Fe 0.7 O 3−δ : a stable high-performance oxygen electrode material for intermediate-temperature solid oxide electrochemical cells". Energy & Environmental Science. 11 (7): 1870–1879. doi:10.1039/C8EE00449H. hdl:11336/99985.

External links edit

  • An electron micrograph of strontium titanate, as artwork entitled "Strontium" at the DeYoung Museum in San Francisco 2013-10-22 at the Wayback Machine

December 07, 2023
strontium, titanate, oxide, strontium, titanium, with, chemical, formula, srtio3, room, temperature, centrosymmetric, paraelectric, material, with, perovskite, structure, temperatures, approaches, ferroelectric, phase, transition, with, very, large, dielectric. Strontium titanate is an oxide of strontium and titanium with the chemical formula SrTiO3 At room temperature it is a centrosymmetric paraelectric material with a perovskite structure At low temperatures it approaches a ferroelectric phase transition with a very large dielectric constant 104 but remains paraelectric down to the lowest temperatures measured as a result of quantum fluctuations making it a quantum paraelectric 1 It was long thought to be a wholly artificial material until 1982 when its natural counterpart discovered in Siberia and named tausonite was recognised by the IMA Tausonite remains an extremely rare mineral in nature occurring as very tiny crystals Its most important application has been in its synthesized form wherein it is occasionally encountered as a diamond simulant in precision optics in varistors and in advanced ceramics Strontium titanate NamesOther names Strontium titanium oxideTausonite STOIdentifiersCAS Number 12060 59 2 Y3D model JSmol Interactive imageInteractive imageChemSpider 74801 YECHA InfoCard 100 031 846EC Number 235 044 1MeSH Strontium titanium oxidePubChem CID 82899UNII OLH4I98373 YCompTox Dashboard EPA DTXSID70893688InChI InChI 1S 3O Sr Ti q 2 1 2 YKey VEALVRVVWBQVSL UHFFFAOYSA N YInChI 1 3O Sr Ti q 2 1 2 rO3Ti Sr c1 4 2 3 q 2 2Key VEALVRVVWBQVSL VUHNDFTMAESMILES Sr O Ti O O Sr 2 O Ti O OPropertiesChemical formula SrTiO3Molar mass 183 49 g molAppearance White opaque crystalsDensity 5 11 g cm3Melting point 2 080 C 3 780 F 2 350 K Solubility in water insolubleRefractive index nD 2 394StructureCrystal structure Cubic PerovskiteSpace group Pm3 m No 221Except where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa Y verify what is Y N Infobox references The name tausonite was given in honour of Lev Vladimirovich Tauson 1917 1989 a Russian geochemist Disused trade names for the synthetic product include strontium mesotitanate Diagem and Marvelite This product is currently being marketed for its use in jewelry under the name Fabulite 2 Other than its type locality of the Murun Massif in the Sakha Republic natural tausonite is also found in Cerro Sarambi Concepcion department Paraguay and along the Kotaki River of Honshu Japan 3 4 Contents 1 Properties 2 Synthesis 3 Use as a diamond simulant 4 Use in radioisotope thermoelectric generators 5 Use in solid oxide fuel cells 6 See also 7 References 8 External linksProperties edit nbsp Atomic resolution image of SrTiO3 acquired using a Scanning Transmission Electron Microscope STEM and a high angle annular dark field HAADF detector Brighter spots are columns of atoms containing Sr and darker spots contain Ti Columns containing only O atoms are not visible nbsp Structure of SrTiO3 The red spheres are oxygens blue are Ti4 cations and the green ones are Sr2 SrTiO3 has an indirect band gap of 3 25 eV and a direct gap of 3 75 eV 5 in the typical range of semiconductors Synthetic strontium titanate has a very large dielectric constant 300 at room temperature and low electric field It has a specific resistivity of over 109 W cm for very pure crystals 6 It is also used in high voltage capacitors Introducing mobile charge carriers by doping leads to Fermi liquid metallic behavior already at very low charge carrier densities 7 At high electron densities strontium titanate becomes superconducting below 0 35 K and was the first insulator and oxide discovered to be superconductive 8 Strontium titanate is both much denser specific gravity 4 88 for natural 5 13 for synthetic and much softer Mohs hardness 5 5 for synthetic 6 6 5 for natural than diamond Its crystal system is cubic and its refractive index 2 410 as measured by sodium light 589 3 nm is nearly identical to that of diamond at 2 417 but the dispersion the optical property responsible for the fire of the cut gemstones of strontium titanate is 4 3x that of diamond at 0 190 B G interval This results in a shocking display of fire compared to diamond and diamond simulants such as YAG GAG GGG Cubic Zirconia and Moissanite 3 4 Synthetics are usually transparent and colourless but can be doped with certain rare earth or transition metals to give reds yellows browns and blues Natural tausonite is usually translucent to opaque in shades of reddish brown dark red or grey Both have an adamantine diamond like lustre Strontium titanate is considered extremely brittle with a conchoidal fracture natural material is cubic or octahedral in habit and streaks brown Through a hand held direct vision spectroscope doped synthetics will exhibit a rich absorption spectrum typical of doped stones Synthetic material has a melting point of ca 2080 C 3776 F and is readily attacked by hydrofluoric acid 3 4 Under extremely low oxygen partial pressure strontium titanate decomposes via incongruent sublimation of strontium well below the melting temperature 9 At temperatures lower than 105 K its cubic structure transforms to tetragonal 10 Its monocrystals can be used as optical windows and high quality sputter deposition targets nbsp Strontium titanate single crystal substrates 5x5x0 5mm The transparent substrate left is pure SrTiO3 and the black substrate is doped with 0 5 weight of niobiumSrTiO3 is an excellent substrate for epitaxial growth of high temperature superconductors and many oxide based thin films It is particularly well known as the substrate for the growth of the lanthanum aluminate strontium titanate interface Doping strontium titanate with niobium makes it electrically conductive being one of the only conductive commercially available single crystal substrates for the growth of perovskite oxides Its bulk lattice parameter of 3 905A makes it suitable as the substrate for the growth of many other oxides including the rare earth manganites titanates lanthanum aluminate LaAlO3 strontium ruthenate SrRuO3 and many others Oxygen vacancies are fairly common in SrTiO3 crystals and thin films Oxygen vacancies induce free electrons in the conduction band of the material making it more conductive and opaque These vacancies can be caused by exposure to reducing conditions such as high vacuum at elevated temperatures High quality epitaxial SrTiO3 layers can also be grown on silicon without forming silicon dioxide thereby making SrTiO3 an alternative gate dielectric material This also enables the integration of other thin film perovskite oxides onto silicon 11 SrTiO3 has been shown to possess persistent photoconductivity where exposing the crystal to light will increase its electrical conductivity by over 2 orders of magnitude After the light is turned off the enhanced conductivity persists for several days with negligible decay 12 13 Due to the significant ionic and electronic conduction of SrTiO3 it is potent to be used as the mixed conductor 14 Synthesis edit nbsp A plate cut out of synthetic SrTiO3 crystalSynthetic strontium titanate was one of several titanates patented during the late 1940s and early 1950s other titanates included barium titanate and calcium titanate Research was conducted primarily at the National Lead Company later renamed NL Industries in the United States by Leon Merker and Langtry E Lynd Merker and Lynd first patented the growth process on February 10 1953 a number of refinements were subsequently patented over the next four years such as modifications to the feed powder and additions of colouring dopants A modification to the basic Verneuil process also known as flame fusion is the favoured method of growth An inverted oxy hydrogen blowpipe is used with feed powder mixed with oxygen carefully fed through the blowpipe in the typical fashion but with the addition of a third pipe to deliver oxygen creating a tricone burner The extra oxygen is required for successful formation of strontium titanate which would otherwise fail to oxidize completely due to the titanium component The ratio is ca 1 5 volumes of hydrogen for each volume of oxygen The highly purified feed powder is derived by first producing titanyl double oxalate salt SrTiO C2O4 2 2 H2O by reacting strontium chloride SrCl2 and oxalic acid COOH 2 2 H2O with titanium tetrachloride TiCl4 The salt is washed to completely eliminate chloride heated to 1000 C in order to produce a free flowing granular powder of the required composition and is then ground and sieved to ensure all particles are between 0 2 0 5 micrometres in size 15 The feed powder falls through the oxyhydrogen flame melts and lands on a rotating and slowly descending pedestal below The height of the pedestal is constantly adjusted to keep its top at the optimal position below the flame and over a number of hours the molten powder cools and crystallises to form a single pedunculated pear or boule crystal This boule is usually no larger than 2 5 centimetres in diameter and 10 centimetres long it is an opaque black to begin with requiring further annealing in an oxidizing atmosphere in order to make the crystal colourless and to relieve strain This is done at over 1000 C for 12 hours 15 Thin films of SrTiO3 can be grown epitaxially by various methods including pulsed laser deposition molecular beam epitaxy RF sputtering and atomic layer deposition As in most thin films different growth methods can result in significantly different defect and impurity densities and crystalline quality resulting in a large variation of the electronic and optical properties Use as a diamond simulant editIts cubic structure and high dispersion once made synthetic strontium titanate a prime candidate for simulating diamond Beginning c 1955 large quantities of strontium titanate were manufactured for this sole purpose Strontium titanate was in competition with synthetic rutile titania at the time and had the advantage of lacking the unfortunate yellow tinge and strong birefringence inherent to the latter material While it was softer it was significantly closer to diamond in likeness Eventually however both would fall into disuse being eclipsed by the creation of better simulants first by yttrium aluminium garnet YAG and followed shortly after by gadolinium gallium garnet GGG and finally by the to date ultimate simulant in terms of diamond likeness and cost effectiveness cubic zirconia 16 Despite being outmoded strontium titanate is still manufactured and periodically encountered in jewellery It is one of the most costly of diamond simulants and due to its rarity collectors may pay a premium for large i e gt 2 carat 400 mg specimens As a diamond simulant strontium titanate is most deceptive when mingled with melee i e lt 0 20 carat 40 mg stones and when it is used as the base material for a composite or doublet stone with e g synthetic corundum as the crown or top of the stone Under the microscope gemmologists distinguish strontium titanate from diamond by the former s softness manifested by surface abrasions and excess dispersion to the trained eye and occasional gas bubbles which are remnants of synthesis Doublets can be detected by a join line at the girdle waist of the stone and flattened air bubbles or glue visible within the stone at the point of bonding 17 18 19 Use in radioisotope thermoelectric generators editDue to its high melting point and insolubility in water strontium titanate has been used as a strontium 90 containing material in radioisotope thermoelectric generators RTGs such as the US Sentinel and Soviet Beta M series 20 21 As strontium 90 has a high fission product yield and is easily extracted from spent nuclear fuel Sr 90 based RTGs can in principle be produced cheaper than those based on plutonium 238 or other radionuclides which have to be produced in dedicated facilities However due to the lower power density 0 45Wthermal per gram of Strontium 90 Titanate and half life space based applications which put a particular premium on low weight high reliability and longevity prefer Plutonium 238 Terrestrial off grid applications of RTGs meanwhile have been largely phased out due to concern over orphan sources and the decreasing price and increasing availability of solar panels small wind turbines chemical battery storage and other off grid power solutions Use in solid oxide fuel cells editStrontium titanate s mixed conductivity has attracted attention for use in solid oxide fuel cells SOFCs It demonstrates both electronic and ionic conductivity which is useful for SOFC electrodes because there is an exchange of gas and oxygen ions in the material and electrons on both sides of the cell H 2 O 2 H 2 O 2 e displaystyle ce H2 O 2 gt H2O 2e nbsp anode 1 2 O 2 2 e O 2 displaystyle ce 1 2O2 2e gt O 2 nbsp cathode Strontium titanate is doped with different materials for use on different sides of a fuel cell On the fuel side anode where the first reaction occurs it is often doped with lanthanum to form lanthanum doped strontium titanate LST In this case the A site or position in the unit cell where strontium usually sits is sometimes filled by lanthanum instead this causes the material to exhibit n type semiconductor properties including electronic conductivity It also shows oxygen ion conduction due to the perovskite structure tolerance for oxygen vacancies This material has a thermal coefficient of expansion similar to that of the common electrolyte yttria stabilized zirconia YSZ chemical stability during the reactions which occur at fuel cell electrodes and electronic conductivity of up to 360 S cm under SOFC operating conditions 22 Another key advantage of these LST is that it shows a resistance to sulfur poisoning which is an issue with the currently used nickel ceramic cermet anodes 23 Another related compound is strontium titanium ferrite STF which is used as a cathode oxygen side material in SOFCs This material also shows mixed ionic and electronic conductivity which is important as it means the reduction reaction which happens at the cathode can occur over a wider area 24 Building on this material by adding cobalt on the B site replacing titanium as well as iron we have the material STFC or cobalt substituted STF which shows remarkable stability as a cathode material as well as lower polarization resistance than other common cathode materials such as lanthanum strontium cobalt ferrite These cathodes also have the advantage of not containing rare earth metals which make them cheaper than many of the alternatives 25 See also editCalcium copper titanateReferences edit K A Muller amp H Burkard 1979 SrTiO3 An intrinsic quantum paraelectric below 4 K Phys Rev B 19 7 3593 3602 Bibcode 1979PhRvB 19 3593M doi 10 1103 PhysRevB 19 3593 Mottana Annibale March 1986 Una brillante sintesi Scienza e Dossier in Italian Giunti 1 1 9 a b c Tausonite Webmineral Retrieved 2009 06 06 a b c Tausonite Mindat Retrieved 2009 06 06 K van Benthem C Elsasser and R H French 2001 Bulk electronic structure of SrTiO3 Experiment and theory Journal of Applied Physics 90 12 6156 Bibcode 2001JAP 90 6156V doi 10 1063 1 1415766 S2CID 54065614 Strontium Titanate ESPI Metals ESPICorp Archived from the original on 2015 09 24 Xiao Lin Benoit Fauque Kamran Behnia 2015 Scalable T2 resistivity in a small single component Fermi surface Science 349 6251 945 8 arXiv 1508 07812 Bibcode 2015Sci 349 945L doi 10 1126 science aaa8655 PMID 26315430 S2CID 148360 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Koonce C S Cohen Marvin L 1967 Superconducting Transition Temperatures of Semiconducting SrTiO3 Phys Rev 163 2 380 Bibcode 1967PhRv 163 380K doi 10 1103 PhysRev 163 380 C Rodenbucher P Meuffels W Speier M Ermrich D Wrana F Krok K Szot 2017 Stability and Decomposition of Perovskite Type Titanates upon High Temperature Reduction Phys Status Solidi RRL 11 9 1700222 Bibcode 2017PSSRR 1100222R doi 10 1002 pssr 201700222 S2CID 102882984 L Rimai amp G A deMars 1962 Electron Paramagnetic Resonance of Trivalent Gadolinium Ions in Strontium and Barium Titanates Phys Rev 127 3 702 Bibcode 1962PhRv 127 702R doi 10 1103 PhysRev 127 702 R A McKee F J Walker amp M F Chisholm 1998 Crystalline Oxides on Silicon The First Five Monolayers Phys Rev Lett 81 14 3014 Bibcode 1998PhRvL 81 3014M doi 10 1103 PhysRevLett 81 3014 Tarun Marianne C Selim Farida A McCluskey Matthew D 2013 Persistent Photoconductivity in Strontium Titanate Physical Review Letters Department of Physics and Astronomy Washington State University Pullman Washington 111 18 187403 Bibcode 2013PhRvL 111r7403T doi 10 1103 PhysRevLett 111 187403 PMID 24237562 Retrieved 2013 11 18 Light Exposure Increases Crystal s Electrical Conductivity 400 fold VIDEO Nature World News Retrieved 2013 11 18 Mixed conductors Max Planck institute for solid state research Retrieved 16 September 2016 a b H J Scheel amp P Capper 2008 Crystal growth technology from fundamentals and simulation to large scale production Wiley VCH p 431 ISBN 978 3 527 31762 2 R W Hesse 2007 Jewelrymaking through history an encyclopedia Greenwood Publishing Group p 73 ISBN 978 0 313 33507 5 Nassau K 1980 Gems made by man Santa Monica California Gemological Institute of America pp 214 221 ISBN 0 87311 016 1 O Donoghue M 2002 Synthetic imitation amp treated gemstones Great Britain Elsevier Butterworth Heinemann pp 34 65 ISBN 0 7506 3173 2 Read P G 1999 Gemmology second edition Great Britain Butterworth Heinemann pp 173 176 177 293 ISBN 0 7506 4411 7 Power Sources for Remote Arctic Applications PDF Washington DC U S Congress Office of Technology Assessment June 1994 OTA BP ETI 129 Standring WJF Selnaes OG Sneve M Finne IE Hosseini A Amundsen I Strand P 2005 Assessment of environmental health and safety consequences of decommissioning radioisotope thermal generators RTGs in Northwest Russia PDF Osteras Norwegian Radiation Protection Authority archived from the original PDF on 2016 03 03 retrieved 2013 12 04 Marina O 2002 Thermal electrical and electrocatalytical properties of lanthanum doped strontium titanate Solid State Ionics 149 1 2 21 28 doi 10 1016 S0167 2738 02 00140 6 Gong Mingyang Liu Xingbo Trembly Jason Johnson Christopher 2007 Sulfur tolerant anode materials for solid oxide fuel cell application Journal of Power Sources 168 2 289 298 Bibcode 2007JPS 168 289G doi 10 1016 j jpowsour 2007 03 026 Jung WooChul Tuller Harry L 2009 Impedance study of SrTi1 xFexO3 d x 0 05 to 0 80 mixed ionic electronic conducting model cathode Solid State Ionics 180 11 13 843 847 doi 10 1016 j ssi 2009 02 008 Zhang Shan Lin Wang Hongqian Lu Matthew Y Zhang Ai Ping Mogni Liliana V Liu Qinyuan Li Cheng Xin Li Chang Jiu Barnett Scott A 2018 Cobalt substituted SrTi 0 3 Fe 0 7 O 3 d a stable high performance oxygen electrode material for intermediate temperature solid oxide electrochemical cells Energy amp Environmental Science 11 7 1870 1879 doi 10 1039 C8EE00449H hdl 11336 99985 External links editAn electron micrograph of strontium titanate as artwork entitled Strontium at the DeYoung Museum in San Francisco Archived 2013 10 22 at the Wayback Machine Retrieved from https en wikipedia org w index php title Strontium titanate amp oldid 1188334799, wikipedia, wiki, book, books, library,

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