Frustule

A frustule is the hard and porous cell wall or external layer of diatoms. The frustule is composed almost purely of silica, made from silicic acid, and is coated with a layer of organic substance, which was referred to in the early literature on diatoms as pectin, a fiber most commonly found in cell walls of plants.^[1]^[2] This layer is actually composed of several types of polysaccharides.^[3]

The frustule's structure is usually composed of two overlapping sections known as thecae (or less formally as valves). The joint between the two thecae is supported by bands of silica (girdle bands) that hold them together. This overlapping allows for some internal expansion room and is essential during the reproduction process. The frustule also contains many pores called areolae and slits that provide the diatom access to the external environment for processes such as waste removal and mucilage secretion.

The microstructural analysis of the frustules shows that the pores are of various sizes, shapes and volume. The majority of the pores are open and do not contain impurities. The dimensions of the nanopores are in the range 250–600 nm.^[4]^[5]^[6]

^ "Diatoms: More on Morphology".
^ Parker, Andrew R.; Townley, Helen E. (3 June 2007). "Biomimetics of photonic nanostructures". Nature Nanotechnology. 2 (6): 347–353. Bibcode:2007NatNa...2..347P. doi:10.1038/nnano.2007.152. PMID 18654305.
^ Progress in Phycological Research: v. 7 (1991) by F.E. Round (Volume editor), David J. Chapman (Volume editor)
^ Reka, Arianit; Anovski, Todor; Bogoevski, Slobodan; Pavlovski, Blagoj; Boškovski, Boško (29 December 2014). "Physical-chemical and mineralogical-petrographic examinations of diatomite from deposit near village of Rožden, Republic of Macedonia". Geologica Macedonica. 28 (2): 121–126.
^ Reka, Arianit A.; Pavlovski, Blagoj; Makreski, Petre (October 2017). "New optimized method for low-temperature hydrothermal production of porous ceramics using diatomaceous earth". Ceramics International. 43 (15): 12572–12578. doi:10.1016/j.ceramint.2017.06.132.
^ Reka, Arianit A.; Pavlovski, Blagoj; Ademi, Egzon; Jashari, Ahmed; Boev, Blazo; Boev, Ivan; Makreski, Petre (31 December 2019). "Effect Of Thermal Treatment Of Trepel At Temperature Range 800-1200˚C". Open Chemistry. 17 (1): 1235–1243. doi:10.1515/chem-2019-0132.

[MM-1] "Diatoms: More on Morphology".

[ParkerTownley2007-2] Parker, Andrew R.; Townley, Helen E. (3 June 2007). "Biomimetics of photonic nanostructures". Nature Nanotechnology. 2 (6): 347–353. Bibcode:2007NatNa...2..347P. doi:10.1038/nnano.2007.152. PMID 18654305.

[PPR_7-3] Progress in Phycological Research: v. 7 (1991) by F.E. Round (Volume editor), David J. Chapman (Volume editor)

[4] Reka, Arianit; Anovski, Todor; Bogoevski, Slobodan; Pavlovski, Blagoj; Boškovski, Boško (29 December 2014). "Physical-chemical and mineralogical-petrographic examinations of diatomite from deposit near village of Rožden, Republic of Macedonia". Geologica Macedonica. 28 (2): 121–126.

[5] Reka, Arianit A.; Pavlovski, Blagoj; Makreski, Petre (October 2017). "New optimized method for low-temperature hydrothermal production of porous ceramics using diatomaceous earth". Ceramics International. 43 (15): 12572–12578. doi:10.1016/j.ceramint.2017.06.132.

[6] Reka, Arianit A.; Pavlovski, Blagoj; Ademi, Egzon; Jashari, Ahmed; Boev, Blazo; Boev, Ivan; Makreski, Petre (31 December 2019). "Effect Of Thermal Treatment Of Trepel At Temperature Range 800-1200˚C". Open Chemistry. 17 (1): 1235–1243. doi:10.1515/chem-2019-0132.

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