Santa Barbara Amorphous-15

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File:SBA-15-powder.jpg
Typical SBA-15 powder sample

SBA-15, an acronym for Santa Barbara Amorphous-15, is a silica-based ordered mesoporous material that was first synthesized by researchers at the university of California Santa Barbra in 1998.[1] This material proved important for scientists in various fields such as material sciences,[2] drug delivery,[3] catalysis,[4] fuel cells[5] and many other due to its desirable properties and ease of production.

Synthesis procedure

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The procedure is a typical Liquid-Crystal templating that consists of three steps:

File:Gel-SBA-15.jpg
The gel obtained in the second synthesis phase.
  1. Solution preparation — Pluronic P123 is dissolved in an acidic solution of water at specific molar ratios[6] and the silica precursor typically TEOS or TMOS (sometimes EGMS[7]) is added and mixed in for some time.
  2. Hydrothermal treatment — The solution is sealed in a container and subjected to a temperature T1 for about 24 hours and then a higher temp T2 for 48 hours.
  3. Washing and calcination — The gel obtained from the previous step is washed with water and ethanol under centrifuging, and finally calcinated at about 550 °C for 6 hours.

Structure

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The interest in SBA-15 comes from the fact that its mostly mesoporous – meaning the pores are in the range of 2 nm to 50 nm according to the IUPAC definition[8] and the fact that these pores have a well defined structure that is cylindrical shape in hexagonal ordering with their relatively thick pore walls which gives thermal stability.[9]

The sorption isotherms of these materials, demonstrate typical hysteretic behavior, which is still under discussion for its causes.[2]

The transmission electron microscopy of the sample shows the cylindrical pores but also highlights the fact that the pores of this material exhibit geometric deformations.

The small-angle X-ray scattering pattern shows typical Bragg peaks to the hexagonal structure of the material. The peak positions, is directly related to the lattice parameter.

qhk=4πa3h2+k2+hk

where h and k are the miller indices.

References

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