Flexible Minerals: Self-Assembled Calcite Spicules with Extreme Bending Strength

Filipe Natalio; Tomas P. Corrales; Martin Panthoefer; Dieter Schollmeyer; Ingo Lieberwirth; Werner E. G. Mueller; Michael Kappl; Hans-Juergen Butt; Wolfgang Tremel

doi:10.1126/science.1216260

Flexible Minerals: Self-Assembled Calcite Spicules with Extreme Bending Strength

Filipe Natalio, Tomas P. Corrales, Martin Panthoefer, Dieter Schollmeyer, Ingo Lieberwirth, Werner E. G. Mueller, Michael Kappl, Hans-Juergen Butt, Wolfgang Tremel^*

^*Corresponding author for this work

Scientific Archeology Unit

Research output: Contribution to journal › Article › peer-review

116 Citations (Scopus)

Abstract

Silicatein-alpha is responsible for the biomineralization of silicates in sponges. We used silicatein-alpha to guide the self-assembly of calcite "spicules" similar to the spicules of the calcareous sponge Sycon sp. The self-assembled spicules, 10 to 300 micrometers (mu m) in length and 5 to 10 mu m in diameter, are composed of aligned calcite nanocrystals. The spicules are initially amorphous but transform into calcite within months, exhibiting unusual growth along [100]. They scatter x-rays like twinned calcite crystals. Whereas natural spicules evidence brittle failure, the synthetic spicules show an elastic response, which greatly enhances bending strength. This remarkable feature is linked to a high protein content. With nano-thermogravimetric analysis, we measured the organic content of a single spicule to be 10 to 16%. In addition, the spicules exhibit waveguiding properties even when they are bent.

Original language	English
Pages (from-to)	1298-1302
Number of pages	6
Journal	Science
Volume	339
Issue number	6125
DOIs	https://doi.org/10.1126/science.1216260
Publication status	Published - 15 Mar 2013

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title = "Flexible Minerals: Self-Assembled Calcite Spicules with Extreme Bending Strength",

abstract = "Silicatein-alpha is responsible for the biomineralization of silicates in sponges. We used silicatein-alpha to guide the self-assembly of calcite {"}spicules{"} similar to the spicules of the calcareous sponge Sycon sp. The self-assembled spicules, 10 to 300 micrometers (mu m) in length and 5 to 10 mu m in diameter, are composed of aligned calcite nanocrystals. The spicules are initially amorphous but transform into calcite within months, exhibiting unusual growth along [100]. They scatter x-rays like twinned calcite crystals. Whereas natural spicules evidence brittle failure, the synthetic spicules show an elastic response, which greatly enhances bending strength. This remarkable feature is linked to a high protein content. With nano-thermogravimetric analysis, we measured the organic content of a single spicule to be 10 to 16%. In addition, the spicules exhibit waveguiding properties even when they are bent.",

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AU - Natalio, Filipe

AU - Corrales, Tomas P.

AU - Panthoefer, Martin

AU - Schollmeyer, Dieter

AU - Lieberwirth, Ingo

AU - Mueller, Werner E. G.

AU - Kappl, Michael

AU - Butt, Hans-Juergen

AU - Tremel, Wolfgang

PY - 2013/3/15

Y1 - 2013/3/15

N2 - Silicatein-alpha is responsible for the biomineralization of silicates in sponges. We used silicatein-alpha to guide the self-assembly of calcite "spicules" similar to the spicules of the calcareous sponge Sycon sp. The self-assembled spicules, 10 to 300 micrometers (mu m) in length and 5 to 10 mu m in diameter, are composed of aligned calcite nanocrystals. The spicules are initially amorphous but transform into calcite within months, exhibiting unusual growth along [100]. They scatter x-rays like twinned calcite crystals. Whereas natural spicules evidence brittle failure, the synthetic spicules show an elastic response, which greatly enhances bending strength. This remarkable feature is linked to a high protein content. With nano-thermogravimetric analysis, we measured the organic content of a single spicule to be 10 to 16%. In addition, the spicules exhibit waveguiding properties even when they are bent.

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JF - Science

IS - 6125

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Flexible Minerals: Self-Assembled Calcite Spicules with Extreme Bending Strength

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