Biofunctional surfaces by plasma electrolytic oxidation on titanium biomedical alloys

Saber Amin Yavari; Bogdan Necula; LIdy Fratila-Apachitei; Jurek Duszczyk; Julian Apachitei

doi:10.1179/1743294415Y.0000000101

Biofunctional surfaces by plasma electrolytic oxidation on titanium biomedical alloys

Saber Amin Yavari, Bogdan Necula, LIdy Fratila-Apachitei, Jurek Duszczyk, Julian Apachitei

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Abstract

he effects of substrate composition on oxide layer properties following plasma electrolytic oxidation under similar conditions have been evaluated for α-cpTi, α/β-Ti6Al7Nb, β-Ti35Zr10Nb and β-Ti45Nb alloys. All oxidised surfaces revealed enhanced wettability, surface free energy and roughness relative to the non-oxidised surfaces. Nevertheless, the resultant oxides differed with respect to average pore size, pores density, layer chemistry and phase composition. The β-titanium alloys developed oxides with a larger average pore size and lower pore density relative to the α-cpTi and α/β-Ti6Al7Nb substrates. Anatase dominated the oxide layer formed on α-cpTi and β-Ti45Nb alloys, a mixture of anatase and rutile was present on the oxidised α/β-Ti6Al7Nb surface, whereas Ti2ZrO6 was the only phase detected on the oxidised surface of the β-Ti35Zr10Nb alloy.

Original language	English
Pages (from-to)	411-417
Journal	Surface Engineering
Volume	32
Issue number	6
DOIs	https://doi.org/10.1179/1743294415Y.0000000101
Publication status	Published - 2016

Keywords

Biomaterials
Titanium
Biofunctional
PEO
Biomedical

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title = "Biofunctional surfaces by plasma electrolytic oxidation on titanium biomedical alloys",

abstract = "he effects of substrate composition on oxide layer properties following plasma electrolytic oxidation under similar conditions have been evaluated for α-cpTi, α/β-Ti6Al7Nb, β-Ti35Zr10Nb and β-Ti45Nb alloys. All oxidised surfaces revealed enhanced wettability, surface free energy and roughness relative to the non-oxidised surfaces. Nevertheless, the resultant oxides differed with respect to average pore size, pores density, layer chemistry and phase composition. The β-titanium alloys developed oxides with a larger average pore size and lower pore density relative to the α-cpTi and α/β-Ti6Al7Nb substrates. Anatase dominated the oxide layer formed on α-cpTi and β-Ti45Nb alloys, a mixture of anatase and rutile was present on the oxidised α/β-Ti6Al7Nb surface, whereas Ti2ZrO6 was the only phase detected on the oxidised surface of the β-Ti35Zr10Nb alloy.",

keywords = "Biomaterials, Titanium, Biofunctional, PEO, Biomedical",

author = "{Amin Yavari}, Saber and Bogdan Necula and LIdy Fratila-Apachitei and Jurek Duszczyk and Julian Apachitei",

year = "2016",

doi = "10.1179/1743294415Y.0000000101",

language = "English",

volume = "32",

pages = "411--417",

journal = "Surface Engineering",

issn = "0267-0844",

publisher = "Maney Publishing",

number = "6",

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TY - JOUR

T1 - Biofunctional surfaces by plasma electrolytic oxidation on titanium biomedical alloys

AU - Amin Yavari, Saber

AU - Necula, Bogdan

AU - Fratila-Apachitei, LIdy

AU - Duszczyk, Jurek

AU - Apachitei, Julian

PY - 2016

Y1 - 2016

N2 - he effects of substrate composition on oxide layer properties following plasma electrolytic oxidation under similar conditions have been evaluated for α-cpTi, α/β-Ti6Al7Nb, β-Ti35Zr10Nb and β-Ti45Nb alloys. All oxidised surfaces revealed enhanced wettability, surface free energy and roughness relative to the non-oxidised surfaces. Nevertheless, the resultant oxides differed with respect to average pore size, pores density, layer chemistry and phase composition. The β-titanium alloys developed oxides with a larger average pore size and lower pore density relative to the α-cpTi and α/β-Ti6Al7Nb substrates. Anatase dominated the oxide layer formed on α-cpTi and β-Ti45Nb alloys, a mixture of anatase and rutile was present on the oxidised α/β-Ti6Al7Nb surface, whereas Ti2ZrO6 was the only phase detected on the oxidised surface of the β-Ti35Zr10Nb alloy.

AB - he effects of substrate composition on oxide layer properties following plasma electrolytic oxidation under similar conditions have been evaluated for α-cpTi, α/β-Ti6Al7Nb, β-Ti35Zr10Nb and β-Ti45Nb alloys. All oxidised surfaces revealed enhanced wettability, surface free energy and roughness relative to the non-oxidised surfaces. Nevertheless, the resultant oxides differed with respect to average pore size, pores density, layer chemistry and phase composition. The β-titanium alloys developed oxides with a larger average pore size and lower pore density relative to the α-cpTi and α/β-Ti6Al7Nb substrates. Anatase dominated the oxide layer formed on α-cpTi and β-Ti45Nb alloys, a mixture of anatase and rutile was present on the oxidised α/β-Ti6Al7Nb surface, whereas Ti2ZrO6 was the only phase detected on the oxidised surface of the β-Ti35Zr10Nb alloy.

KW - Biomaterials

KW - Titanium

KW - Biofunctional

KW - PEO

KW - Biomedical

U2 - 10.1179/1743294415Y.0000000101

DO - 10.1179/1743294415Y.0000000101

M3 - Article

SN - 0267-0844

VL - 32

SP - 411

EP - 417

JO - Surface Engineering

JF - Surface Engineering

IS - 6

ER -

Biofunctional surfaces by plasma electrolytic oxidation on titanium biomedical alloys

Abstract

Keywords

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