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Materials Science-Poland
Volume 34 (2016): Issue 1 (March 2016)
Open Access
Implant materials modified by colloids
Beata Zboromirska-Wnukiewicz
Beata Zboromirska-Wnukiewicz
,
Witold Wnukiewicz
Witold Wnukiewicz
,
Krzysztof Kogut
Krzysztof Kogut
,
Jan Wnukiewicz
Jan Wnukiewicz
,
Roman Rutowski
Roman Rutowski
,
Jerzy Gosk
Jerzy Gosk
and
Krzysztof Kasprzyk
Krzysztof Kasprzyk
| Apr 27, 2016
Materials Science-Poland
Volume 34 (2016): Issue 1 (March 2016)
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Article Category:
Research Article
Published Online:
Apr 27, 2016
Page range:
33 - 37
Received:
Mar 07, 2015
Accepted:
Nov 12, 2015
DOI:
https://doi.org/10.1515/msp-2016-0006
Keywords
implant
,
electrokinetic potential
,
nanosilver
,
bioceramic
© 2016 Wroclaw University of Technology
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
Fig. 1
The size and shape of the particles separated from the stable colloid. A – SEM microscope image, B – AFM microscope image.
Fig. 2
The size and shape of the particles separated from the stable colloid – TEM microscope images.
Fig. 3
Gauss and Nicomp distributions of stable colloidal silver.
Fig. 4
Electrokinetic potential of colloidal silver in the function of pH.
Fig. 5
Scanning microscope image of corundum ceramics surface designed for implantation. A – corundum ceramics, B – corundum ceramics infiltrated by colloidal silver.
Crystal sizes determined by the X-ray diffraction method.
Type
Residue from the suspension obtained
with 1.1 kJ energy
Results
Intensity I
15041
6306
2912
4431
1248
895
5454
Diffraction angle 2Θ
44.9
52.4
77.3
94.1
99,8
123.9
148.3
Crystallite size D [A
˚
]
190.2
148.6
166.6
125.1
130.2
106.6
119.6