AFM Nanoindentations of Diatom Biosilica Surfaces
Abstract
Diatoms have intricately and uniquely nanopatterned silica exoskeletons (frustules) and are a common target of biomimetic investigations. A better understanding of the diatom frustule structure and function at the nanoscale could provide new insights for the biomimetic fabrication of nanostructured ceramic materials and lightweight, yet strong, scaffold architectures. Here, we have mapped the nanoscale mechanical properties of Coscinodiscus sp. diatoms using atomic force microscopy (AFM)-based nanoindentation. Mechanical properties were correlated with the frustule structures obtained from high-resolution AFM and scanning electron microscopy (SEM). Significant differences in the micromechanical properties for the different frustule layers were observed. A comparative study of other related inorganic material including porous silicon films and free-standing membranes as well as porous alumina was also undertaken- Image
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- Biophysics
- Medicine
- Physiology
- Biotechnology
- Ecology
- Computational Biology
- Environmental Sciences not elsewhere classified
- Biological Sciences not elsewhere classified
- Physical Sciences not elsewhere classified
- Mechanical properties
- Significant differences
- frustule structures
- scaffold architectures
- Diatom Biosilica SurfacesDiatoms
- biomimetic fabrication
- AFM Nanoindentations
- nanoscale
- SEM
- force microscopy
- biomimetic investigations
- silicon films
- material
- diatom frustule structure
- scanning electron microscopy
- micromechanical properties
- frustule layers
- Coscinodiscus sp
- nanopatterned silica exoskeletons
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Last time updated on 16/03/2018
This paper was published in The Francis Crick Institute.
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