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High Pressure Research
An International Journal
Volume 32, 2012 - Issue 1
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Selected papers from the XLIXth Conference of the European High Pressure Research Group (EHPRG), held in Budapest (Hungary), 28 August–2 September 2011

Surface influence on the behavior of stabilized zirconia nanoparticles under pressure

Oksana Gorban Donetsk Institute for Physics and Engineering of the NAS of Ukraine, Donetsk, UkraineCorrespondence[email protected]
,
Susanna Synyakina Donetsk Institute for Physics and Engineering of the NAS of Ukraine, Donetsk, Ukraine
,
Galina Volkova Donetsk Institute for Physics and Engineering of the NAS of Ukraine, Donetsk, Ukraine
,
Yurii Kulik Ivan Franko National University of L'viv, L'viv, Ukraine
&
Tetyana Konstantinova Donetsk Institute for Physics and Engineering of the NAS of Ukraine, Donetsk, Ukraine
Pages 72-80 | Received 22 Aug 2011, Accepted 04 Jan 2012, Published online: 27 Apr 2012

References

  • Maruya , K. , Komiya , T. , Hayakawa , T. and Yashima , L. M. 2000 . Active sites on ZrO2 for the formation of isobutene from CO and H2 . J. Mol. Catal. A: Chem. , 159 : 97 – 102 .
  • Kelly , J. R. and Denry , I. 2008 . Stabilized zirconia as a structural ceramic: An overview . Dental Mater. , 24 : 289 – 298 .
  • Mitshuhashi , T. , Ichihara , M. and Tatsuke , U. 1974 . Characterization and stabilization of metastable tetragonal ZrO2 . J. Am. Ceram.Soc. , 57 ( 2 ) : 97 – 101 .
  • T. Konstantinova, I. Danilenko, N. Pilipenko, and A. Dobrikov, Application of physical actions to processes of production of zirconia based powder and ceramics. 9th Cimtec – World Ceramics Congress. Ceramics: Getting into the 2000’s. Part A. P. Vincenzini (ed.), Techna Srl., Hardbound, 1999, pp. 305–312.
  • Shukla , S. and Seal , S. 2005 . Mechanisms of room temperature metastable tetragonal phase stabilisation in zirconia . Int. Mater. Rev. , 50 : 1 – 20 .
  • Li , P. and Chen , I. 1994 . Effect of dopants on zirconia stabilization – an X-ray absorbtion study: III. Charge-compensative dopants . J. Am. Ceram. Soc. , 77 : 1289 – 1295 .
  • Sahu , H. R. and Rao , G. R. 2000 . Characterization of combustion synthesized zirconia powder by UV–vis, IR and other techniques . Bull. Mater. Sci. , 23 : 349 – 354 .
  • Ju-Nam , Y. and Lead , J. R. 2008 . Manufactured nanoparticles: An overview of their chemistry, interactions and potential environmental implications . Sci. Total Env. , 400 : 396 – 414 .
  • Caruso , F. 2001 . Nanoengineering of particle surfaces . Adv. Mater. , 13 : 11 – 22 .
  • Chuah , G. K. and Jaenicke , S. 1997 . The preparation of high surface area zirconia – —influence of precipitating agent and digestion . Appl. Catal. A , 163 : 261 – 273 .
  • Thomé , L. , Gentils , A. , Jagielski , J. , Garrido , F. and Thomé , T. 2006 . Physicochemical modifications induced by ion bombardment and thermal treatments in zirconia and spinel . Nucl. Instrum. Methods Phys. Res. Section B: Beam Interactions Mater. Atoms , 250 : 106 – 113 .
  • Ackerman , R. J. , Garg , S. P. and Rauh , E. G. 1977 . High-temperature phase diagram for the system Zr‒O . J. Am. Ceram. Soc. , 60 : 341 – 345 .
  • Kisi , E. H. and Howard , C. J. 1998 . Crystal structure of zirconia phases and their interrelation . Key Eng. Mater. , 153–154 : 1 – 36 .
  • Garvie , R. C. 1965 . The occurrence of metastable tetragonal zirconia as a crystallite size effect . J. Phys. Chem. , 69 : 1238 – 1243 .
  • Yoshimura , M. 1988 . Phase stability of zirconia . Bull. Am. Ceram. Soc. , 67 : 1950 – 1955 .
  • Chevalier , J. , Gremillard , L. , Virkar , A. V. and Clarke , D. 2009 . The tetragonal–monoclinic transformation in zirconia: Lessons learned and future trends . J. Am. Ceram. Soc. , 92 : 1901 – 1920 .
  • Alzyab , B. , Perry , C. H. and Ingel , R. P. 1987 . High pressure phase transformation in zirconia and yttria-doped zirconia . J. Am. Ceram. Soc. , 70 ( 10 ) : 760 – 765 .
  • Svergun , D. I. 1992 . Determination of the regularization parameter in indirect-transform methods using perceptual criteria . J. Appl. Crystallogr. , 25 : 495 – 503 .
  • Bale , H. D. and Schmidt , P. W. 1984 . Small-angle X-ray-scattering investigation of submicroscopic porosity with fractal properties . Phys. Rev. Lett. , 53 : 596 – 599 .
  • Feinberg , A. and Perry , C. H. 1981 . Structural disorder and phase transition in ZrO2–Y2O3 systems . J. Phys. Chem. Solids , 42 : 513 – 518 .
  • Hirata , T. , Asari , E. and Kitajima , M. 1994 . Infrared and Raman spectroscopic studies of ZrO2 polymorphs doped with Y2O3 or CeO2 . J. Solid State Chem. , 110 : 201 – 207 .
  • Mondal , A. and Ram , S. 2003 . Formation of a new polymorph of ZrO2 with orthorhombic crystal structure contained in a mesoporous structure . Chem. Phys. Lett. , 382 : 297 – 306 .
  • Bannuch , O. A. , Povarova , K. B. and Kapustin , V. I. 2002 . The new approach to superficial ionization and drift-spectroscopy of organic molecules . J. Tech. Phys. , 72 : 88 – 93 .
  • Konstantinova , T. , Danilenko , I. , Glazunova , V. , Volkova , G. and Gorban , O. 2011 . Mesoscopic phenomena in oxide nanoparticles systems: Processes of growth . J. Nanopart. Res. , 13 : 4015 – 4023 .
  • Chraska , T. , King , A. H. and Berndt , C. C. 2000 . On the size-dependent phase transformation in nanoparticulate zirconia . Mat. Sci. Eng. A , 286 : 169 – 178 .
  • Mondal , A. and Ram , S. 2004 . Reconstructive phase formation of ZrO2 nanoparticles in a new orthorhombic crystal structure from an energized porous ZrO(OH)2 xH2O precursor . Ceram. Int. , 30 : 239 – 249 .
  • Valmalette , J. Ch. and Isa , M. 2002 . Size effects on the stabilization of ultrafine zirconia . Nanoparticles Chem. Mater. , 14 : 5098 – 5102 .
  • Li , S. , Zheng , W. T. and Jiang , Q. 2006 . Size and pressure effects on solid transformation temperatures of ZrO2 . Scr. Mater. , : 2091 – 2094 .
  • Ortiz , A. L. , Sanchez-Gonzalez , J. , Gonzalez-Mendez , L. M. and Cumbrera , F. L. 2007 . Determination of the thermal stability and isothermal bulk modulus of the ZrO2 polymorphs at room temperature by molecular dynamics with a semi-empirical quantum-chemical model . Ceram. Int. , 33 : 705 – 709 .

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