Cvjetinovic, Julijana; Luchkin, Sergey; Statnik, Eugene; Davidovich, Nickolai; Vyazemsky, T I; Scientic, Karadag; Somov, Pavel; Korsunsky, Alexander; Gorin, Dmitry
Diatoms are single cell microalgae enclosed in silica exoskeletons (frustules) that provide inspiration for advanced hybrid nanostructure designs mimicking multi-scale porosity to achieve outstanding mechanical and optical properties. Interrogating the structure and properties of diatoms down to nanometer scale leads to breakthrough advances reported here in the nanomechanical characterization of Coscinodiscus oculus-iridis diatom pure silica frustules, as well as of air-dried and wet cells with organic content. Static and dynamic mode Atomic Force Microscopy (AFM) and in-SEM nanoindentation revealed the peculiarities of diatom response with separate contributions from material nanoscale behavior and membrane deformation of the entire valve. The deformation response depends strongly on silica hydration and on the support from the internal organic content. Lessons from Nature’s nanostructuring of diatoms open up pathways to new generations of nano-and microdevices for electronic, electromechanical, photonic, liquid, energy storage, and other applications.