Comparison of sol-gel and co-precipitation methods on the structural properties and phase transformation of  γ and α-Al2O3 nanoparticles

doi:10.1007/s40436-013-0018-1

Advances in Manufacturing

Comparison of sol-gel and co-precipitation methods on the structural properties and phase transformation of γ and α-Al₂O₃ nanoparticles

A. Rajaeiyan • M. M. Bagheri-Mohagheghi

School of Physics, Damghan University, Damghan, Iran

收稿日期:2012-12-21 修回日期:2013-03-05 出版日期:2013-06-25 发布日期:2013-03-29
通讯作者: e-mail: m_mohagheghee@yahoo.co.uk
作者简介:e-mail: m_mohagheghee@yahoo.co.uk

Comparison of sol-gel and co-precipitation methods on the structural properties and phase transformation of γ and α-Al₂O₃ nanoparticles

A. Rajaeiyan • M. M. Bagheri-Mohagheghi

School of Physics, Damghan University, Damghan, Iran

Received:2012-12-21 Revised:2013-03-05 Online:2013-06-25 Published:2013-03-29
Contact: e-mail: m_mohagheghee@yahoo.co.uk
About author:e-mail: m_mohagheghee@yahoo.co.uk

摘要/Abstract

摘要： The nanostructured c and a alumina powders were synthesized by sol-gel and co-precipitation methods,and properties of the powders were studied by XRD, SEM,TEM, BET and FTIR. The results showed that both c and a phases were formed in the lower temperature in precipitation method compared to sol-gel. The size of spherical aalumina synthesized by sol-gel was 10–15 nm, whereas the sample prepared by co-precipitation yielded nearly spherical and hexagon a-powder with particle size of 10–50 nm.At 750 ℃ the resulting powder prepared by co-precipitation exhibited larger surface area (206.2 m2/g) compared to sol-gel (30.72 m2/g), hence it is recommended for catalytic and sensing applications.

关键词: &gamma, and α-Al₂O₃ , Co-precipitation, , Sol-gel , Nanoparticles

Abstract: The nanostructured c and a alumina powders were synthesized by sol-gel and co-precipitation methods,and properties of the powders were studied by XRD, SEM,TEM, BET and FTIR. The results showed that both c and a phases were formed in the lower temperature in precipitation method compared to sol-gel. The size of spherical aalumina synthesized by sol-gel was 10–15 nm, whereas the sample prepared by co-precipitation yielded nearly spherical and hexagon a-powder with particle size of 10–50 nm.At 750 ℃ the resulting powder prepared by co-precipitation exhibited larger surface area (206.2 m2/g) compared to sol-gel (30.72 m2/g), hence it is recommended for catalytic and sensing applications.

Key words: &gamma, and α-Al₂O₃ , Co-precipitation, , Sol-gel , Nanoparticles

A. Rajaeiyan,M. M. Bagheri-Mohagheghi. Comparison of sol-gel and co-precipitation methods on the structural properties and phase transformation of γ and α-Al₂O₃ nanoparticles[J]. Advances in Manufacturing, doi: 10.1007/s40436-013-0018-1.

参考文献

1. Pathak LC, Singh TB, Das S, Verma AK, Ramachandrarao P(2002) Effect of pH on the combustion synthesis of nano-crystalline alumina powder. Mater Lett 57:380–385

2. Wang Z, Liu Y, Zhang Z (2002) Hand book of nanophase and nano structure material. Online access

3. Kuiry SC, Megen E, Patil SD, Deshpande SA, Seal S (2005) Solution-based chemical synthesis of boehmite nanofibers and alumina nanorods. J Phys Chem B 109:3868–3872

4. Niihara K (1991) New design concept of structural ceramics–ceramic nanocomposite. J Ceram Soc Jpn 99:974

5. Gates BC (1995) Supported metal clusters: synthesis, structure,and catalysis. Chem Rev 95:511–522

6. Schneider JM, Sproul WD, Voevodin AA, Matthews A (1997) Crystalline alumina deposited at low temperatures by ionized magnetron sputtering. J Vac Sci Technol A Vac Surf Films 15:1084–1088

7. Krell A, Ma HW (2003) Performance of alumina membranes from new nanosynthesis in ultrafiltration and nanofiltration. J Am Ceram Soc 86:241–246

8. Trueba M, Trasatti SP (2005) Gamma-alumina as a support for catalysis: a review of fundamental aspects. Eur J Inorg Cheminform 36:3393–3403

9. Gitzen WH (ed) (1970) Alumina as a ceramic material. American Ceramic Society, Columbus

10. Ezugwu EU, Bonney J, da Silva (2004) Evaluation of the performance  of different nano-ceramic tool grades when machining  nickel-base, Inconel 718. Alloy J Braz Soc Mech Sci Eng   XXVI(1):12–16

11. Perry RH (1984) Chemical engineers handbook, 6th edn.McGraw-Hill, New York, p 23

12. Tikkanen J, Gross KA, Berndt CC, Pitkanen V, Keskinen J,Raghu S, Rajala M, Karthikeyan J (1997) Characteristics of the liquid flame spray process. Surf Coat Technol 90:210–216

13. Souza Santosa P, Souza Santos H, Toledo SP (2000) Standard  transition aluminas. Electron Microsc Stud Mater Res 3:104–114

14. Bodaghi M, Mirhabibi A, Tahriri MR, Zolfonoon H, Karimi M (2006) Mechanochemical assisted synthesis and powder characteristics of nanostructure ceramic of a-Al₂O₃ at room

temperature. Mater Sci Eng 162:155–161

15. Johnston G, Munenchausen R, Smith DM, Fahrenholtz W, Foltyn  S (1992) Reactive laser ablation synthesis of nanosize alumina powder. J Am Ceram Soc 75:3293–3298

16. Tok AI, Boey FYC, Zhao XL (2006) Novel synthesis of Al₂O₃nano-particles by flame spray pyrolysis. J Mater Process Technol 178:270–273

17. Pivkina A, Ivanov D, Frolov Y, Mudretsova S, Nickolskaya A,Schoonman J (2006) Plasma synthesized nano-aluminum powders.J Therm Anal Calorim 86:733

18. Nguefack M, Popa AF, Rossignol S, Kappenstein C (2003) Preparation of alumina through a sol-gel process. Synthesis,characterization, thermal evolution and model of intermediate boehmite. Chem Chem Phys 5:4279–4289

19. Mishara D, Anand S, Panda RK, Das RK (2000) Hydrothermal preparation and characterization of boehmites. Mater Lett 42:38–45

20. Rahmanpour O, Shariati A, Khosravi Nikou MR (2012) New method for synthesis nano size c-Al2O3 catalyst for dehydration of methanol to dimethyl ether. Int J Chem Eng Appl 3

(2):125–128

21. Zhai X, Fu Y (2006) Combustion synthesis of the nano structured  alumina powder. Nanoscience 11:286–292

22. Kamata K, Mochizuki T, Matsumoto S, Yamada A, Miyokawa K  (1985) Preparation of submicrometer A12O3 powder by gasphase  oxidation of tris (acetylacetonato) aluminum (111). J Am Ceram 68:193–194

23. Wang X, Lu G, Guo Y, Wang Y, Guo Y (2005) Preparation of high thermal-stabile alumina by reverse microemulsion method.Mater Chem Phys 90:225–229

24. Parida KM, Pradhan AC, Das J, Sahu N (2009) Synthesis and characterization of nano-sized porous gamma-alumina by control precipitation method. Mater Chem Phys 113:244–248

25. Potdar HS, Jun KW, Bae JW, Kim SM, Lee YJ (2007) Synthesis of nano-sized porous c-alumina powder via a precipitation/digestion route. Appl Catal A 321:109–116

26. Rogojan R, Andronescu E, Ghitulica C, Stefan B (2011) Synthesis  and characterization of alumina nano-powder by sol-gel method. UPB Sci Bull Ser B 73(2): 67–76

27. Mirjalili F, Mohamad H, Chuah L (2011) Preparation of nano scale a-Al2O3 powder by the sol-gel method. Ceramics – Silika´ty  55(4):378–383

28. Banerjee S, Sujatha P (2007) Effect of citrate to nitrate ratio on the decomposition characteristics and phase formation of alumina.J Therm Anal Calorim 90:699–706

29. Zhan X, Honkanen M, Leva E (2008) Transition alumina nanoparticles and nanorods from boehmite nanoflakes. J Crystal Growth 310:3674–3679

30. Gan Z, Ning G, Lin Y, Cong Y (2007) Morphological control of mesoporous alumina nanostructures via template-free solvothermal synthesis. Mater Lett 61:3758–3761

31. Kim H, Kim T, Kim J, Park S, Hong S, Lee G (2008) Influences of precursor and additive on the morphology of nanocrystalline aalumina.J Phys Chem Solids 69:1521–1524

32. Ramanathan S, Roy SK, Bhat R, Upadhyaya DD, Biswas AR  (1997) Alumina powders from aluminium nitrate-urea and aluminium sulphate-urea reactions: the role of the precursor anion and process conditions on characteristic. Ceram Int 23:45–53

33. Li J, Yubai P, Xiang C, Ge Q, Guo J (2006) Low temperature synthesis of ultrafine a-Al2O3 by a simple aqueous sol-gel process.Ceram Int 32:578–591

34. Macedo M, Osawa C, Bertran A (2004) sol-gel synthesis of transparent alumina gel and pure gamma alumina by urea hydrolysis of aluminum nitrate. J Sol Gel Sci Technol

30:135–140

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Comparison of sol-gel and co-precipitation methods on the structural properties and phase transformation of γ and α-Al₂O₃ nanoparticles

Comparison of sol-gel and co-precipitation methods on the structural properties and phase transformation of γ and α-Al₂O₃ nanoparticles

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