Pulsed electron beam surface melting of CoCrMo alloy for biomedical applications
Pulsed electron beam surface melting of CoCrMo alloy for biomedical applications
The use of CoCrMo alloys in biomedical applications has come under scrutiny recently due to unacceptable revision rates of certain hip resurfacing and total hip arthroplasty designs. Failure analysis has demonstrated that solid and soluble wear debris and corrosion products, released from the joints have resulted in adverse local tissue reactions (ALTR), pseudo-tumour formation and ultimately implant retrieval and replacement. In order to improve the surface properties of a wrought CoCrMo alloy, a low energy high current pulsed electron beam surface treatment process was investigated. Samples were irradiated at two cathode voltages of 15 and 35 kV at pulse numbers of 1, 15 and 25. At low beam energies a polishing effect was observed as a result of surface melting. At higher beam energies a higher Ra value was the result of the formation of surface craters. Nano-indentation and scratch testing of the treated surface were carried out using a nano-indenter. Depth profiling nano-indentation was performed using a Berkovich tip in load control. Loading was performed in 8 mN increments up to 160 mN at a rate of 3.5 mN/s, with a 60 s dwell period and 40% unloading. The results demonstrated that the surface treatment process reduced both the modulus and the hardness of the surface in comparison to the control. Scratching was performed with a 20 ?m radius spherical diamond and loading rate of 2 mN/s up to a maximum of 100 mN, over a 1 mm scratch length. Similar scratch depths for both control and treated surfaces were observed. However, an improvement in the dynamic friction coefficient was observed at certain beam energies. These results are discussed in the light of XRD evidence that suggested rapid cooling of the surface induced preferential formation of an ?-martensite HCP phase which may be beneficial for biomedical applications.
CoCrMo, electron beam melting, XRD, nano-indentation, scratch test, friction
250-256
Walker, J.C.
b300eafd-5b0a-4cf5-86d2-735813b04c6f
Cook, R.B.
06f8322d-81be-4f82-9326-19e55541c78f
Murray, J.W.
3985aa41-1e0e-4504-ab90-e31a00c33c38
Clare, A.T.
07b7d19d-56e4-4a3d-9be8-0a7446257fa4
April 2013
Walker, J.C.
b300eafd-5b0a-4cf5-86d2-735813b04c6f
Cook, R.B.
06f8322d-81be-4f82-9326-19e55541c78f
Murray, J.W.
3985aa41-1e0e-4504-ab90-e31a00c33c38
Clare, A.T.
07b7d19d-56e4-4a3d-9be8-0a7446257fa4
Walker, J.C., Cook, R.B., Murray, J.W. and Clare, A.T.
(2013)
Pulsed electron beam surface melting of CoCrMo alloy for biomedical applications.
Wear, 301 (1-2), .
(doi:10.1016/j.wear.2013.02.002).
Abstract
The use of CoCrMo alloys in biomedical applications has come under scrutiny recently due to unacceptable revision rates of certain hip resurfacing and total hip arthroplasty designs. Failure analysis has demonstrated that solid and soluble wear debris and corrosion products, released from the joints have resulted in adverse local tissue reactions (ALTR), pseudo-tumour formation and ultimately implant retrieval and replacement. In order to improve the surface properties of a wrought CoCrMo alloy, a low energy high current pulsed electron beam surface treatment process was investigated. Samples were irradiated at two cathode voltages of 15 and 35 kV at pulse numbers of 1, 15 and 25. At low beam energies a polishing effect was observed as a result of surface melting. At higher beam energies a higher Ra value was the result of the formation of surface craters. Nano-indentation and scratch testing of the treated surface were carried out using a nano-indenter. Depth profiling nano-indentation was performed using a Berkovich tip in load control. Loading was performed in 8 mN increments up to 160 mN at a rate of 3.5 mN/s, with a 60 s dwell period and 40% unloading. The results demonstrated that the surface treatment process reduced both the modulus and the hardness of the surface in comparison to the control. Scratching was performed with a 20 ?m radius spherical diamond and loading rate of 2 mN/s up to a maximum of 100 mN, over a 1 mm scratch length. Similar scratch depths for both control and treated surfaces were observed. However, an improvement in the dynamic friction coefficient was observed at certain beam energies. These results are discussed in the light of XRD evidence that suggested rapid cooling of the surface induced preferential formation of an ?-martensite HCP phase which may be beneficial for biomedical applications.
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More information
Accepted/In Press date: 4 February 2013
e-pub ahead of print date: 12 February 2013
Published date: April 2013
Keywords:
CoCrMo, electron beam melting, XRD, nano-indentation, scratch test, friction
Organisations:
Energy Technology Group, nCATS Group
Identifiers
Local EPrints ID: 350434
URI: http://eprints.soton.ac.uk/id/eprint/350434
ISSN: 0043-1648
PURE UUID: a84a2f1d-9623-4e27-96cb-a2d18b3cd487
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Date deposited: 26 Mar 2013 10:24
Last modified: 15 Mar 2024 03:34
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Author:
J.W. Murray
Author:
A.T. Clare
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