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HomeMaterials Science ForumMaterials Science Forum Vols. 539-543Nanoscale Behaviour of Certain Materials/Surfaces

Nanoscale Behaviour of Certain Materials/Surfaces

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Abstract:

Nanoscale studies of four important phenomena – in-situ development of high temperature (HT) wear resistant nanostructured surface glaze, the initial stages of oxidation of TiAl intermetallics, the high temperature degradation of DLC coatings and the property change promoted by nano-patterning of a TiO2 surface are described.

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THERMEC 2006

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Periodical:

Materials Science Forum (Volumes 539-543)

Pages:

5007-5012

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.539-543.5007

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Online since:

March 2007

Authors:

Psantu K. Datta, Zbigniew Klusek, Hai Liang Du, Jim. S. Burnell-Gray

Keywords:

DLC, Glaze Layer, Graphite, Nano-Patterning, Nanoscale, Oxidation, TiAl, Wear

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© 2007 Trans Tech Publications Ltd. All Rights Reserved

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[1] P .D. Wood: PhD Thesis The Effect of the Counterface on the Wear Resistance of Certain Alloys at Room Temperature and 750°C, Northumbria University, UK, (1997).

[2] S. Rose: PhD Thesis Studies of the High Temperature Tribological Behaviour of Some Superalloys, Northumbria University, UK, (2000).

[3] I.A. Inman: PhD Thesis, Compacted Oxide Layer Formation Under Conditions of Limited Debris Retention at the Wear Interface During High Temperature Sliding Wear of Superalloys, Northumbria University, UK, (2003).

[4] F.H. Stott, D.S. Lin and G.C. Wood: Corr. Sci. Vol. 13 (1973), p.449.

[5] J-N. Aoh and J-C. Chen: Wear Vol. 250-251 (2001), p.611.

[6] J. Singh and A.T. Alpas: Metall. Mater. Trans. A Vol. 27A (1996), p.3135.

[7] H.L. Du, P.K. Datta, I. Inman, E. Kuzmann, K. Süvegh, T. Marek and A. Vértes: Tribology Letters Vol. 18 (2005), p.393.

[8] I.A. Inman, P.K. Datta, H.L. Du, J.S. Burnell-Gray, S. Pierzgalski and Q. Luo: Tribology International Vol. 39 (2005), p.812.

DOI: 10.1016/j.triboint.2005.02.007

[9] I.A. Inman, S. Datta, H.L. Du, J.S. Burnell-Gray and Q. Luo: Wear Vol. 254 (2003), p.461.

[10] H.L. Du, P.K. Datta, I. Inman, R. Geurts and C. Kübel: Mater. Sci. Eng. A Vol. 357 (2003), p.412.

[11] G.H. Mei, in: Oxidation of High Temperature Intermetallics, edited by T. Grobstein and J. Doychak, The Minerals, Metals and Materials Society (1989).

[12] J.L. Smialek and D.L. Humphrey: Scripta Metall. Mater. Vol. 26 (1992), p.1763.

[13] G. Welsh, S. Freidman and A. Kahveci, in: Microscopy of Oxidation, edited by M.J. Bennett and G.W. Lorimer, Institute of Materials, London (1991).

[14] G. Meier and F.S. Pettit: Mater. Sci. Eng. A Vol. 153 (1992), p.548.

[15] G. Meier and F.S. Pettit: Mater. Sci. Technol. Vol. 8 (1992), p.331.

[16] C. Chaze and J. Coddett: Mater. Sci. Vol. 22 (1987), p.1206.

[17] H.L. Du, P.K. Datta, D. Lewis and J.S. Burnell-Gray: Corros. Sci. Vol. 36 (1994), p.631.

[18] H.L. Du, P.K. Datta, D. Lewis and J.S. Burnell-Gray: Oxid. Met. Vol. 45 (1996), p.197.

[19] Y. Shida and H. Anada: Oxid. Met. Vol. 45 (1996), p.197.

[20] Kwok-On Ng and D. Vanderbilt: Phys. Rev. Vol. B56 (1997), p.10544.

[21] E. Asari and R. Souda: Phys. Rev. Vol. B60 (1999), p.10719.

[22] V. E. Henrich, G. Dresselhaus and H. J. Zeiger: Phys. Rev. Lett. Vol. 36 (1976), p.1335.

[23] J. Geng, G. Gantner, P. Oelhafen, P.K. Datta: Appl. Surf. Sci. Vol. 158 (2000), p.65.

[24] Z. Klusek, Z. Waqar, W. Kozlowski, P. Kowalczyk, E. Denisov, I. Makarenko, T. Kompaniets, A. N. Titkov and P. K. Datta: Appl. Surf. Sci. Vol. 187 (2002), p.28.

DOI: 10.1016/s0169-4332(01)00651-1

[25] Z. Klusek: Appl. Surf. Sci. Vol. 151 (1999), p.251.

[26] E. Sugimura, N. Kitamura and H. Mauhara, in: Nanostructures and Quantum Effects, edited by H. Sakaki and H. Nogoe, Springer Series in Materials Science 31 (1994).