CONVERSION OF Navicula salinicola STRAIN NLA SILICA INTO ALUMINOSILICATE FOR A CATALYTIC REACTION OF ETHYL TERT-BUTYL ETHER SYNTHESIS
The cell wall of diatom Navicula salinicola contains nanopore silica with a unique <br /> <br /> morphology, high mechanical strength, and large surface area. The diatom cell wall <br /> <br /> as been applied for a gas sensor, microfilter, drug delivery agent, and battery &l...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/30534 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The cell wall of diatom Navicula salinicola contains nanopore silica with a unique <br />
<br />
morphology, high mechanical strength, and large surface area. The diatom cell wall <br />
<br />
as been applied for a gas sensor, microfilter, drug delivery agent, and battery <br />
<br />
electrode. However, the diatom cell wall use for a catalyst in ethyl tertiary butyl ether <br />
<br />
(ETBE) synthesis has not been studied yet. The objective of the research was to <br />
<br />
convert N. salinicola strain NLA silica into aluminosilicate, and to apply the <br />
<br />
aluminosilicate as catalyst for the synthesis of ETBE. The methods included <br />
<br />
cultivation of N. salinicola strain NLA, separation and purification of the diatom <br />
<br />
silica, conversion of the silica into aluminosilicate, physical characterization of the <br />
<br />
silica and the aluminosilicate, and determination of aluminosilicate catalytic activity. <br />
<br />
The results showed that the density of N. salinicola strain NLA with an initial density <br />
<br />
of 1 × 105 cell/mL for 7 d was 6.56 ± 0.38 g/L. The wet biomass contained 9.57% <br />
<br />
water, 26.66% organic compound, and 63.77% silica. The content of purified silica <br />
<br />
obtained from the wet biomass of N. salinicola strain NLA was 100%. The shape of <br />
<br />
the silica was boat like with a cell length of 15–30 μm, cell width of 6–8 μm, and pore <br />
<br />
size of 74–328 nm. The silica has been successfully converted into aluminosilicate <br />
<br />
that was identified by Si–O–Si vibration bands at wave numbers of 453, 802, and <br />
<br />
1109 cm-1 and O–Al–O vibration bands at wave numbers of 553, and 1230 cm-1. The <br />
<br />
aluminosilcate was fine sphere crystals with a diameter range of 611–1590 nm. The <br />
<br />
aluminosilicate crystal had a similar structure with ZSM-5 crystal. The <br />
<br />
aluminosilicate showed a catalytic activity on the etherification reaction of ethanol <br />
<br />
and tert-butanol. The main product of ETBE was obtained from the reaction at 80 oC <br />
<br />
for 1 h. This results indicated that the N. salinicola strain NLA cell wall might use for <br />
<br />
raw material of aluminosilicate catalyst. |
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