Wetting and bonding characteristics of selected liquid metals with a high-power diode-laser-treated alumina bioceramic

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Abstract

Changes in the wettability characteristics of an alumina bioceramic occasioned by high-power diode-laser (HPDL) surface treatment were apparent from the observed reduction in the contact angle. Such changes were due to the HPDL bringing about reductions in the surface roughness, increases in the surface O2 content and increases in the polar component of the surface energy. Additionally, HPDL treatment of the alumina-bioceramic surface was found to effect an improvement in the bonding characteristics by increasing the work of adhesion. An electronic approach was used to elucidate the bonding characteristics of the alumina bioceramic before and after HPDL treatment. It is postulated that HPDL-induced changes to the alumina bioceramic produced a surface with a reduced band-gap energy, which consequently increased the work of adhesion by increasing the electron transfer at the metal-oxide interface and thus the metal-oxide interactions. Furthermore, it is suggested that the increase in the work of adhesion of the alumina bioceramic after HPDL treatment was due to a correlation existing between the wettability and ionicity of the alumina bioceramic, for it is believed that the HPDL-treated surface is less ionic in nature than the untreated surface and therefore exhibits better wettability characteristics.

Original languageEnglish
Pages (from-to)1723-1735
Number of pages13
JournalProceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences
Volume460
Issue number2046
DOIs
Publication statusPublished - 8 Jun 2004
Externally publishedYes

Fingerprint

High Power Diode Laser
Bioceramics
Liquid Metal
Alumina
Wetting
liquid metals
Liquid metals
wetting
Semiconductor lasers
aluminum oxides
semiconductor lasers
Wettability
Adhesion
wettability
adhesion
metal oxides
Oxides
Metals
Surface Treatment
Electron Transfer

Keywords

  • Alumina
  • Bioceramic
  • Bonding
  • High-power diode laser (HPDL)
  • Wettability

ASJC Scopus subject areas

  • Mathematics(all)
  • Engineering(all)
  • Physics and Astronomy(all)

Cite this

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title = "Wetting and bonding characteristics of selected liquid metals with a high-power diode-laser-treated alumina bioceramic",
abstract = "Changes in the wettability characteristics of an alumina bioceramic occasioned by high-power diode-laser (HPDL) surface treatment were apparent from the observed reduction in the contact angle. Such changes were due to the HPDL bringing about reductions in the surface roughness, increases in the surface O2 content and increases in the polar component of the surface energy. Additionally, HPDL treatment of the alumina-bioceramic surface was found to effect an improvement in the bonding characteristics by increasing the work of adhesion. An electronic approach was used to elucidate the bonding characteristics of the alumina bioceramic before and after HPDL treatment. It is postulated that HPDL-induced changes to the alumina bioceramic produced a surface with a reduced band-gap energy, which consequently increased the work of adhesion by increasing the electron transfer at the metal-oxide interface and thus the metal-oxide interactions. Furthermore, it is suggested that the increase in the work of adhesion of the alumina bioceramic after HPDL treatment was due to a correlation existing between the wettability and ionicity of the alumina bioceramic, for it is believed that the HPDL-treated surface is less ionic in nature than the untreated surface and therefore exhibits better wettability characteristics.",
keywords = "Alumina, Bioceramic, Bonding, High-power diode laser (HPDL), Wettability",
author = "J. Lawrence",
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T1 - Wetting and bonding characteristics of selected liquid metals with a high-power diode-laser-treated alumina bioceramic

AU - Lawrence, J.

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N2 - Changes in the wettability characteristics of an alumina bioceramic occasioned by high-power diode-laser (HPDL) surface treatment were apparent from the observed reduction in the contact angle. Such changes were due to the HPDL bringing about reductions in the surface roughness, increases in the surface O2 content and increases in the polar component of the surface energy. Additionally, HPDL treatment of the alumina-bioceramic surface was found to effect an improvement in the bonding characteristics by increasing the work of adhesion. An electronic approach was used to elucidate the bonding characteristics of the alumina bioceramic before and after HPDL treatment. It is postulated that HPDL-induced changes to the alumina bioceramic produced a surface with a reduced band-gap energy, which consequently increased the work of adhesion by increasing the electron transfer at the metal-oxide interface and thus the metal-oxide interactions. Furthermore, it is suggested that the increase in the work of adhesion of the alumina bioceramic after HPDL treatment was due to a correlation existing between the wettability and ionicity of the alumina bioceramic, for it is believed that the HPDL-treated surface is less ionic in nature than the untreated surface and therefore exhibits better wettability characteristics.

AB - Changes in the wettability characteristics of an alumina bioceramic occasioned by high-power diode-laser (HPDL) surface treatment were apparent from the observed reduction in the contact angle. Such changes were due to the HPDL bringing about reductions in the surface roughness, increases in the surface O2 content and increases in the polar component of the surface energy. Additionally, HPDL treatment of the alumina-bioceramic surface was found to effect an improvement in the bonding characteristics by increasing the work of adhesion. An electronic approach was used to elucidate the bonding characteristics of the alumina bioceramic before and after HPDL treatment. It is postulated that HPDL-induced changes to the alumina bioceramic produced a surface with a reduced band-gap energy, which consequently increased the work of adhesion by increasing the electron transfer at the metal-oxide interface and thus the metal-oxide interactions. Furthermore, it is suggested that the increase in the work of adhesion of the alumina bioceramic after HPDL treatment was due to a correlation existing between the wettability and ionicity of the alumina bioceramic, for it is believed that the HPDL-treated surface is less ionic in nature than the untreated surface and therefore exhibits better wettability characteristics.

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