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2017 | OriginalPaper | Chapter

5. Preparation Techniques and Crystal Growth Processes

Authors : Mohammed A. Gondal, Chang Xiaofeng, Mohamed A. Dastageer

Published in: Novel Bismuth-Oxyhalide-Based Materials and their Applications

Publisher: Springer India

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Abstract

This chapter presents different preparation methods for bismuth oxyhalides and their relative merits, characteristics, and applicability. The method of preparation of different variants of bismuth oxyhalides includes various hydrolysis methods, preparation by heat treatment, vapor-phase synthesis, hydrothermal preparation, solvothermal preparation, and special halide source-induced preparation.

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previous chapter Optical Properties of Bismuth Oxyhalides

next chapter Modified Bismuth Oxihalide Semiconductors

Keller E, Krämer V (2005) A strong deviation from Vegard’s rule: X-Ray powder investigations of the three quasi-binary phase systems BiOX–BiOY (X, Y = Cl, Br, I). Zeitschrift für Naturforschung B 60:1255–1263

Zheng GQ, Tang MT (2000) Phases of residue in distillation of BiCl3–HCl–H2O system. Chin J Nonferrous Met 10:250–252

Wang Y, Peng W, Chai L (2004) Thermodynamic equilibrium of bismuth hydrometallurgy in chloride and nitrate solutions. J Cent South Univ Technol 11:410–413CrossRef

Wosylus A, Hoffmann S, Schmidt M et al (2010) In-situ study of the solid-gas reaction of BiCl₃ to BiOCl via the intermediate hydrate BiCl₃·H₂O. Eur J Inorg Chem 2010:1469–1471CrossRef

Peng HL, Chan CK, Meister S et al (2009) Shape evolution of layer-structured bismuth oxychloride nanostructures via low-temperature chemical vapor transport. Chem Mater 21:247–252CrossRef

Novokreshchenova MN, Yukhin Y, Bokhonov BB (2005) Highly pure bismuth (III) oxochloride synthesis. Chem Sustain Deve 13:563–568

Ye LQ, Zan L, Tian LH et al (2011) The 001 facets-dependent high photoactivity of BiOCl nanosheets. Chem Commun 47:6951–6953CrossRef

Lee KS, Myung ST, Amine K et al (2009) Dual functioned BiOF-coated Li[Li_0.1Al_0.05Mn_1.85]O₄ for lithium batteries. J Mater Chem 19:1995–2005CrossRef

Kang HB, Myung ST, Amine K et al (2010) Improved electrochemical properties of BiOF-coated 5V spinel Li[Ni_0.5Mn_1.5]O₄ for rechargeable lithium batteries. J Power Sources 195:2023–2028CrossRef

10.

Su WY, Wang J, Huang YX et al (2010) Synthesis and catalytic performances of a novel photocatalyst BiOF. Scripta Mater 62:345–348CrossRef

11.

Wang M, Huang QL, Chen XT et al (2007) Room temperature synthesis of bismuth oxyfluoride nanosheets and nanorods. Mater Lett 61:4666–4669CrossRef

12.

Bervas M, Yakshinskiy B, Klein LC et al (2006) Soft-chemistry synthesis and characterization of bismuth oxyfluorides and ammonium bismuth fluorides. J Am Ceram Soc 89:645–651CrossRef

13.

Ye LQ, Tian LH, Peng TY et al (2011) Synthesis of highly symmetrical BiOI single-crystal nanosheets and their 001 facet-dependent photoactivity. J Mater Chem 21:12479–12484CrossRef

14.

Yu CL, Fan CF, Yu JC et al (2011) Preparation of bismuth oxyiodides and oxides and their photooxidation characteristic under visible/UV light irradiation. Mater Res Bull 46:140–146CrossRef

15.

Ueda W, Sakyu F, Isozaki T et al (1991) Catalytic oxidative dimerization of methane to form C₂-compounds over Arppe’s phase oxychlorides of Bi, La and Sm. Catal Lett 10:83–90CrossRef

16.

Silvestri VJ, Sedgwick TO, Landermann JB (1973) Vapor growth of Bi₁₂GeO₂₀, γ-Bi₂O₃ and BiOCl. J Cryst Growth 20:165–168

17.

Keramidas KG, Voutsas GP, Rentzeperis PI (1993) The crystal structure of BiOCl. Z Kristallogr 205:35–40

18.

Ganesha R, Arivuoli D, Ramasamy P (1993) Growth of some group V–VI–VII compounds from the vapour. J Cryst Growth 128:1081–1085CrossRef

19.

Schuisky M, Hårsta A (1998) Chemical vapor deposition stability diagram for the BiI₃–O₂ system. Electrochem Soc 145:4234–4239CrossRef

20.

Xiong J, Cheng G, Li G et al (2011) Well-crystallized square-like 2D BiOCl nanoplates: mannitol-assisted hydrothermal synthesis and improved visible-light-driven photocatalytic performance. RSC Adv 1:1542–1553CrossRef

21.

Deng ZT, Chen D, Peng B et al (2008) From bulk metal Bi to two-dimensional well-crystallized BiOX (X = Cl, Br) micro- and nanostructures: synthesis and characterization. Cryst Growth Des 8:2995–3003CrossRef

22.

Zhu LY, Xie Y, Zheng XW et al (2002) Growth of compound Bi^III–VI^A–VII^A crystals with special morphologies under mild conditions. Inorg Chem 41:4560–4566CrossRef

23.

Yuan RS, Lin C, Wu BC et al (2009) Synthesis of SnO₂, Fe₂O₃, and BiOCl fibers from inorganic salts by a templating route. Eur J Inorg Chem 2009:3537–3540CrossRef

24.

Zhong LS, Hu JS, Liang HP et al (2006) Self-assembled 3D flowerlike iron oxide nanostructures and their application in water treatment. Adv Mater 18:2426–2431CrossRef

25.

Cao AM, Hu JS, Liang HP et al (2005) Self-assembled Vanadium Pentoxide (V₂O₅) hollow microspheres from nanorods and their application in lithium-ion batteries. Angew Chem Int Ed 44:4391–4395CrossRef

26.

Wang YL, Jiang XC, Xia YN (2003) A solution-phase, precursor route to polycrystalline SnO₂ nanowires that can be used for gas sensing under ambient condition. J Am Chem Soc 125:16176–16177CrossRef

27.

Zhang X, Ai ZH, Jia FL et al (2008) Generalized one-pot synthesis, characterization, and photocatalytic activity of hierarchical BiOX (X = Cl, Br, I) nanoplate microspheres. J Phys Chem C 112:747–753CrossRef

28.

Zhang J, Shi FJ, Lin J et al (2008) Self-assembled 3-D architectures of BiOBr as a visible light-driven photocatalyst. Chem Mater 20:2937–2941CrossRef

29.

Zhu LP, Liao GH, Bing NC et al (2010) Self-assembled 3D BiOCl hierarchitectures: tunable synthesis and characterization. CrystEngComm 12:3791–3796CrossRef

30.

Song JM, Mao CJ, Niu HL et al (2010) Hierarchical structured bismuth oxychlorides: self-assembly from nanoplates to nanoflowers via a solvothermal route and their photocatalytic properties. CrystEngComm 12:3875–3881CrossRef

31.

Ma JM, Liu XD, Lian JB et al (2010) Ionothermal synthesis of BiOCl nanostructures via a long-chain ionic liquid precursor route. Cryst Growth Des 10:2522–2527CrossRef

32.

Cheng HF, Huang BB, Wang ZY et al (2011) One-pot miniemulsion-mediated route to BiOBr hollow microspheres with highly efficient photocatalytic activity. Chem Eur J 17:8039–8043CrossRef

33.

Xia JX, Yin S, Li HM et al (2011) Improved visible light photocatalytic activity of sphere-like BiOBr hollow and porous structures synthesized via a reactable ionic liquid. Dalton Trans 40:5249–5258CrossRef

34.

Xia JX, Yin S, Li HM et al (2011) Self-assembly and enhanced photocatalytic properties of BiOI hollow microspheres via a reactable ionic liquid. Langmuir 27:1200–1206CrossRef

35.

Xia JX, Yin S, Li HM et al (2011) Enhanced photocatalytic activity of bismuth oxyiodine (BiOI) porous microspheres synthesized via reactable ionic liquid-assisted solvothermal method. Colloids Surf A Physicochem Eng Aspects 387:23–28CrossRef

36.

Shang M, Wang WZ, Zhang L et al (2009) Preparation of BiOBr lamellar structure with high photocatalytic activity by CTAB as Br source and template. J Hazard Mater 167:803–809CrossRef

37.

Xiao PP, Zhu LL, Zhu YC et al (2011) Selective hydrothermal synthesis of BiOBr microflowers and Bi₂O₃ shuttles with concave surfaces. J Solid State Chem 184:1459–1464CrossRef

38.

Ai ZH, Ho WK, Lee SC et al (2009) Efficient photocatalytic removal of NO in indoor air with hierarchical bismuth oxybromide nanoplate microspheres under visible light. Environ Sci Technol 43:4143–4150CrossRef

39.

Xu J, Meng W, Zhang Y et al (2011) Photocatalytic degradation of tetrabromobisphenol A by mesoporous BiOBr: efficacy, products and pathway. Appl Catal B Environ 107:355–362CrossRef

40.

Chen YJ, Wen M, Wu QS (2011) Stepwise blossoming of BiOBr nanoplate-assembled microflowers and their visible-light photocatalytic activities. CrystEngComm 13:3035–3039CrossRef

41.

Feng YC, Li L, Li JW et al (2011) Synthesis of mesoporous BiOBr 3D microspheres and their photodecomposition for toluene. J Hazard Mater 192:538–544CrossRef

42.

Liu HQ, Gu XN, Chen F et al (2011) Preparation of nano BiOCl microsphere and its fabrication machanism. Chin J Catal 32:129–134CrossRef

43.

Chen F, Liu HQ, Bagwasi S et al (2010) Photocatalytic study of BiOCl for degradation of organic pollutants under UV irradiation. J Photochem Photobiol A Chem 215:76–80CrossRef

44.

Wang CH, Shao CL, Liu YC et al (2008) Photocatalytic properties BiOCl and Bi₂O₃ nanofibers prepared by electrospinning. Scripta Mater 59:332–335CrossRef

45.

Yu CL, Zhou WQ, Yu JC (2011) Rapid fabrication of BiOCl(Br) nanosheets with high photocatalytic performance via ultrasound irradiation. Chin J Inorg Chem 27:2033–2038

46.

Zheng L, Cao XF, Chen XT et al (2011) BiOBr hierarchical microspheres: microwave-assisted solvothermal synthesis, strong adsorption and excellent photocatalytic properties. J Colloid Interface Sci 354:630–636CrossRef

47.

Henle J, Simon P, Frenzel A et al (2007) Nanosized BiOX (X = Cl, Br, I) particles synthesized in reverse microemulsions. Chem Mater 19:366–373CrossRef

Title: Preparation Techniques and Crystal Growth Processes
Authors: Mohammed A. Gondal
Chang Xiaofeng
Mohamed A. Dastageer
Publisher: Springer India
Book: Novel Bismuth-Oxyhalide-Based Materials and their Applications
Print ISBN: 978-81-322-3737-2

Electronic ISBN: 978-81-322-3739-6

Copyright Year: 2017
DOI: https://doi.org/10.1007/978-81-322-3739-6_5