МИНЕРАЛЫ И ПАРАГЕНЕЗИСЫ МИНЕРАЛОВ КРИСТАЛЛОХИМИЯ СТИЛЛУЭЛЛИТОПОДОБНОГО BaBPO 5 ПО ДАННЫМ МОНОКРИСТАЛЬНОЙ ДИФРАКТОМЕТРИИ В НЕСТАНДАРТНЫХ УСЛОВИЯХ

Кржижановская; Горелова, Л; Копылова, Ю; Верещагин, О; Даль Бо, Ф; Панькин, Д; Hatert, Frédéric

doi:10.31857/S0869605524020082

Article (Scientific journals)

МИНЕРАЛЫ И ПАРАГЕНЕЗИСЫ МИНЕРАЛОВ КРИСТАЛЛОХИМИЯ СТИЛЛУЭЛЛИТОПОДОБНОГО BaBPO 5 ПО ДАННЫМ МОНОКРИСТАЛЬНОЙ ДИФРАКТОМЕТРИИ В НЕСТАНДАРТНЫХ УСЛОВИЯХ

Кржижановская; Горелова, Л; Копылова, Ю et al.

2024 • In Proceedings of the Russian Mineralogical Society, CLIII (2)

Peer Reviewed verified by ORBi

Permalink
https://hdl.handle.net/2268/326029

DOI
10.31857/S0869605524020082

Files (1)Send to Details Statistics Bibliography Similar publications

Files

Full Text

_BaBPO5.pdf

Publisher postprint (1.97 MB)

Download

All documents in ORBi are protected by a user license.

Send to

RIS BibTex APA Chicago Permalink X Linkedin

Details

Abstract :

[ru] Stillwellite-(Ce) and some its synthetic analogues tend to undergo phase transition from polar (ferroelectric) to nonpolar (paraelectric) modification on heating. However, the reasons for the transition and phase stability remain the subject of scientific debate. Here we present detail studies (scanning electron microscopy, energy-dispersive X-ray spectroscopy, Raman spectroscopy and single-crystal X-ray diffraction (SCXRD)) of hydrothermally grown BaBPO5 isostructural with stillwellite-(Ce). Its thermal behavior was studied by an in situ low- (from –173 to +25 °C) and high-temperature (HT; 25–800 °C) SCXRD. Fully ordered crystal structure of BaBPO5 (at T = 25 °C: trigonal, P3221, a = 7.1166(1) Å, c = 7.0011(1) Å, V = 307.07(1) Å3, R1 = 1.42 %) does not exhibit any change of symmetry upon cooling / heating unlike natural stillwellite-(Ce). Thermal expansion of BaBPO5 is almost isotropic (αmin = 8.4, αmax = 8.7⋅10-6 °C-1) despite the chain nature of borophosphate anion. The comparative crystal chemical analysis of HT behavior of cationic polyhedra in the stillwellite-family members is presented.

Disciplines :

Earth sciences & physical geography

Author, co-author :

Кржижановская; Санкт-Петербургский государственный университет, Санкт-Петербург, Россия ; Институт химии силикатов Российской академии наук, Санкт-Петербург, Россия

Горелова, Л; Санкт-Петербургский государственный университет, Санкт-Петербург, Россия

Копылова, Ю; Санкт-Петербургский государственный университет, Санкт-Петербург, Россия ; Институт химии силикатов Российской академии наук, Санкт-Петербург, Россия

Верещагин, О; Санкт-Петербургский государственный университет, Санкт-Петербург, Россия

Даль Бо, Ф; Laboratory of Mineralogy, University of Liège, Belgium

Панькин, Д; Санкт-Петербургский государственный университет, Санкт-Петербург, Россия

Hatert, Frédéric ; Université de Liège - ULiège > Département de géologie > Minéralogie et cristallochimie

Language :

Russian

Title :

Publication date :

15 April 2024

Journal title :

Proceedings of the Russian Mineralogical Society

ISSN :

0869-6055

eISSN :

2658-4352

Publisher :

The Russian Academy of Sciences

Volume :

CLIII

Issue :

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

https://journals.rcsi.science/0869-6055/article/viewFile/263457/242283

Available on ORBi :

since 31 December 2024

Statistics

Number of views

70 (5 by ULiège)

Number of downloads

53 (1 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

OpenAlex citations

Bibliography

Achary S.N., Tyagi A.K. Strong anisotropic expansion of cristobalite-type BPO4 . J. Solid State Chem. 2004. Vol. 177. P. 3918–3926.
Agakhanov A.A., Pautov L.A., Karpenko V.Yu., Bekenova G.K., Uvarova Yu.A. Orlovite, KLi2 TiSi4 O11 F, a new mineral of the mica group. New Data on Minerals. 2011. Vol. 46. P. 13–19.
Agakhanov A.A., Pautov L.A., Sokolova, E., Hawthorne F.C., Karpenko V.Yu, Siidra Oleg I., Muftakhov V.A. Odigitriaite, CsNa5 Ca5 [Si14 B2 O38 ]F2, a new caesium borosilicate mineral from the Darai-Pioz alkaline massif, Tajikistan: Description and crystal structure. Miner. Mag. 2017. Vol. 81. P. 113– 122.
Bubnova R.S., Filatov S.K. High-temperature borate crystal chemistry. Z. Krist.-Cryst. Mater. 2013. Vol. 228. N. 9. P. 1646.
Bubnova R.S., Firsova V.A., Filatov S.K. Software for determining the thermal expansion tensor and the graphic representation of its characteristic surface (ThetaToTensor-TTT). Glass Phys. Chem. 2013. Vol. 39. P. 347–350.
Belokoneva E.L., David W.I.F., Forsyth J.B., Knight K.S. Structures and phase transitions of PrBGeO5 in the temperature range 20–800 ºC. J. Phys-Condens. Mat. 1998. Vol. 10. P. 9975–89.
Belokoneva E.L., Shuvaeva V.A., Antipin M.Yu., Leonyuk N.I. Crystal structure of a high-temperature modification of LaBSiO5, a synthetic analog of stillwellite. Zh. Neorg. Khimii. 1996. Vol. 41. P. 1097– 1101.
Burns P.C., Hawthorne F.C., MacDonald D.J., della Ventura G., Parodi G.C. The crystal structure of stillwellite. Canad. Miner. 1993. Vol. 31. P. 147–152.
Dolomanov O.V., Blake A.J, Champness N.R., Schroder M. OLEX: new software for visualization and analysis of extended crystal structures. J. Appl. Crystallogr. 2013. Vol. 36. P. 1283–1284.
Filatov S.K., Bubnova R.S. Borate сrystal сhemistry. Physics and Chemistry of Glasses. 2000. Vol. 41. N 5. P. 216–224.
Ewald B., Huang Y.-X., Kniep R. Structural chemistry of borophosphates, metalloborophosphates, and related compounds. Z. Anorg. Allg. Chem. 2007. Vol. 633. P. 1517–1540.
Gorelova L.A., Vereshchagin O.S., Aslandukov A., Aslandukova A., Spiridonova D., Krzhizhanovskaya M., Kasatkin A., Dubrovinsky L. Hydroxylherderite (Ca2 Be2 P2 O8 (OH)2 ) stability under extreme conditions (up to 750 °C/100 GPa). J. Amer. Ceram. Soc. 2023. Vol. 106. P. 2622–2634.
Hazen R.M., Finger L.W., Agrawaln D.K., McKinstry H.A., Perrotta A.G. High-temperature crystal chemistry of sodium zirconium phosphate (NZP). J. Mater. Res. 1987. Vol. 2. P. 329–337.
Hazen R.M., Downs R.T. High-Temperature and High Pressure Crystal Chemistry. Rev. Miner. Geochem. 2000. Vol. 41.
Hirtopanu P., Andersen C.J., Fairhurst J.R., Jakab G. Allanite-(Ce) and its associations, from the Ditrau alkaline intrusive massif. Proc. Rom. Acad., Series B. 2013. Vol. 15. P. 59–74.
Huminicki D.M.C., Hawthorne F.C. The Crystal Chemistry of the Phosphate Minerals, Rev. Miner. Geochem. 2002. Vol. 48. N 1. P. 123–253. Inorganic Crystal Structure Database (ICSD). 2023.
Juwhari H.K., White W.B. Luminescence of rare earth borosilicates with the stillwellite and related structures. Mater. Lett. 2010. Vol. 64. N 15. P. 1751–1754.
Kniep R., Gözel G., Eisenmann B., Röhr C., Asbrand M., Kizilyalli M. Borophosphates – a neglected class of compounds: Crystal structures of MII[BPO5 ] (MII = Ca, Sr) and Ba3 [BP3 O12 ]. Angew. Chem. 1994. Vol. 106. P. 791–793.
Krzhizhanovskaya M.G., Kopylova Yu.O., Obozova E.D., Zalesskii V.G., Lushnikov S.G., Gorelova L.A., Shilovskikh V.V., Ugolkov V.L., Britvin S.N., Pekov I.V. Thermal evolution of stillwellite, CeBSiO5, a natural prototype for a family of NLO-active materials. J. Solid. State Chem. 2023. Vol. 318. Nо 123786.
Krzhizhanovskaya M.G., Vereshchagin J.S., Kopylova Yu.O., Gorelova L.A., Pankin D.V., Yukhno V.A., Vlasenko N.S., Bocharov V.M., Britvin S.N. The structural origin and boundaries of thermal transitions in stillwellite-type LnBSiO5 . Opt. Mater. 2024. Vol. 147. 114651.
Lei B., Jing Q., Yang Z., Pan S. Anomalous second-harmonic generation response in SrBPO5 and BaBPO5 . J. Mater. Chem. C. 2015. Vol. 3. P. 1557–1566.
McAndrew J., Scott T.R. Stillwellite, a new rare-earth mineral from Queensland. Nature. 1955. Vol. 176. P. 509.
Krzhizhanovskaya M.G., Vereshchagin J.S., Kopylova Yu.O., Gorelova L.A., Pankin D.V., Yukhno V.A., Vlasenko N.S., Bocharov V.M., Britvin S.N. The structural origin and boundaries of thermal transitions in stillwellite-type LnBSiO5 . Opt. Mater. 2024. Vol. 147. 114651.
Moore P.B., Ghose S. A novel face-sharing octahedral trimer in the crystal structure of Seamanite. Amer. Miner. 1971. Vol. 56. P. 1527–1538.
Nakae H., Kihara K., Hirano S. The crystal structure of the quartz-type form of GaPO4 and its temperature dependence. Z. Krist. 1995. Vol. 210. P. 746–753.
Neumann H., Bergstøl S., Nilssen B. Contributions to the mineralogy of Norway. No. 34. Stillwellite in the Langesundfjord nepheline syenite pegmatite dykes. Norsk Geologisk Tidsskrift [Norweg. J. Geol.] 1966. Vol. 46. P. 327–334.
Onodera A., Belov A.A., Taraskin S.A., Yamashita H., Uesu Y. Thermal and dielectric properties of a new ferroelectric LaBGeO. J. Phys. Soc. Jpn. 1992. Vol. 62. P. 4311–15.
Pan S., Wu Y., Fu P., Zhang G., Wang G., Guan X., Du C., Chen C. The growth of BaBPO5 crystals from Li4 P2 O7 flux. J. Cryst. Growth. 2002. Vol. 236. P. 613–616.
Pan S., Wu X., Fu P.Z., Guochun G., Chenxia Du C, Chuangyan C., Zhang H., Liu Q., Chen X., Yang J., Zhuang W., Rao G. Study on the growth, structure of nonlinear optical crystal BaBPO5 . Rengong Jingti Xuebao. 2003. Vol. 32. P. 281–285.
Pautov L.A., Agakhanov A.A., Sokolova E.V., Hawthorne F., Karpenko V.Yu. Byzantievite, Ba5 (Ca,REE,Y)22 (Ti,Nb)18 (SiO4 )4 [(PO4 ),(SiO4 )]4 (BO3 )9 O21 [(OH),F]4 3(H2 O)1.5, a new mineral. New Data on Minerals. 2011. Vol. 46. P. 5–12.
Pekov I.V., Zubkova N.V., Koshlyakova N.N., Belakovskiy D.I., Agakhanov A.A., Sidorov E.G., Rhabdoborite-(V), rhabdoborite-(Mo) and rhabdoborite-(W): a new group of borate minerals with the general formula Mg12 M113 /O6 [(BO3 )6–x (PO4 )x F2–x ] (M = V5+, Mo6+ or W6+ and x < 1). Phys. Chem. Minerals. 2020. Vol. 47. P. 44.
Petersen O.V. List of all minerals identified in the Ilímaussaq alkaline complex, South Greenland. Geol. Greenland Surv. Bull. 2001. Vol. 190. P. 25–35.
Pushcharovskii D.Yu., Gobechiya E.R., Pasero M., Merlino S., Dimitrova O.V. Hydrothermal synthesis and crystal structures of (Li, Ba)-nanoborate, LiBaB9 O15, and Ba-borophosphate, BaBPO5 . J. Alloy. Compd. 2002. Vol. 339. P. 70–75.
Raade G., Grice J.D., Erambert M., Kristiansson P., Witzke T. Proshchenkoite-(Y) from Russia – a new mineral species in the vicanite group: descriptive data and crystal structure. Miner. Mag. 2008. Vol. 72. P. 1071–1082.
Shannon R.D. Revised Effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides, Acta Crystallogr. A. 1976. Vol. 32. 751–767.
Sen Gupta P.K., Swihart G.H., Dimitrijevic R., Hossain M.B. The crystal structure of lueneburgite, Mg3 (H2 O)6 (B2 (OH)6 (PO4 )2 ). Amer. Miner. 1991. Vol. 76. P. 1400–1407.
Sheldrick G.M. Crystal structure refinement with SHELXL. Acta Cryst. 2015. Vol. 71. P. 3–8.
Shi Y., Liang J.-K., Zhang H., Yang J.-L., Zhuang W.D., Rao G.-H. Crystal structure and vibrational spectra studies of stillwellite compounds NdBSiO5 . J. Alloy. Compd. 1997. Vol. 259. P. 163–169.
Sokolova E., Hawthorne F.C., Pautov L.A., Agakhanov A.A. Byzantievite, Ba5 (Ca,REE,Y)22 (Ti,Nb)18 (SiO4 )4 [(PO4 ),(SiO4 )]4 (BO3 )9 O21 [(OH),F]43 (H2 O)1.5: the crystal structure and crystal chemistry of the only known mineral with the oxyanions (BO3 ), (SiO4 ) and (PO4 ). Miner. Mag. 2010. Vol. 74. P. 285–308.
Søerensen H. (Eds.): The Ilimaussaq alkaline complex, South Greenland: status of mineralogical research with new results. Geol. Greenland Surv. Bull. 2001. Vol. 190. 167 p.
Stefanovich S.Yu., Mill B., Sigaev V.N. Processing and characterisation of ferro/piezoelectrics in the stillwellite family. Ferroelectrics. 1997. Vol. 201. P. 285–294.
Uvarova Y.A., Sokolova E., Hawthorne F.C., Agakhanov A.A., Karpenko V.Y., Pautov L.A. The crystal structure of laptevite-(Ce), NaFe2+(REE7 Ca5 Y3 )(SiO4 )4 (Si3 B2 PO18 )(BO3 )F11, a new mineral species from the Darai-Pioz alkaline massif, Northern Tajikistan. Z. Kristallogr.-Cryst. Mater. 2013. Vol. 228. P. 550–557.
Voronkov A.A., Pyatenko Y.A. X-ray diffraction study of the atomic structure of stillwellite CeBO[SiO4 ]. Sov. Phys. Cryst. 1967. Vol. 12. P. 214–220.
Zhang J., Wang D., Zhang D., Zhang Q., Sun D., Yin S. In situ investigation of BaBPO5 crystal growth mechanism by high-temperature Raman spectroscopy. J. Mol. Struct. 2017. Vol. 1138. P. 50–54.