DECARBOXYLATION (OXIDATIVE) SATURATED FATTY ACIDS TO BIOHYDROCARBONS AT LOW TEMPERATURES
Indonesia has been a net importer of crude oil plus petroleum fuels since 2004. With the gradually declining domestic crude oil production, whereas the need for fuel continues to increase along with the country's economic growth, the counytry’s import of petroleum fuels plus crude oil increa...
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id-itb.:763022023-08-14T12:09:26ZDECARBOXYLATION (OXIDATIVE) SATURATED FATTY ACIDS TO BIOHYDROCARBONS AT LOW TEMPERATURES Hendrik Teknik tertentu, alat, perlengkapan, materi Indonesia Final Project Decarboxylation, manganese(II) acetate, hydrocarbons, enzymes INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/76302 Indonesia has been a net importer of crude oil plus petroleum fuels since 2004. With the gradually declining domestic crude oil production, whereas the need for fuel continues to increase along with the country's economic growth, the counytry’s import of petroleum fuels plus crude oil increases year after year. Therefore, for the sake of national energy security, Indonesia needs to be able to produce alternative fuels within the country. The study of the Gibbs free energy changes of C12 to C16 fatty acids decarboxylation reactions into bioalkanes or bioalkenes with one less carbon atoms than the original fatty acids showed that the reactions are thermodynamically feasible and could achieve complete conversion, even at room temperature. Further literature study showed that manganese(II) acetate have the potential to become catalyst for the autoxidative decarboxylation of these fatty acids. The objective of proposed research is to either prove or disprove the potential of the catalyst candidate. In this study, Mn(II) acetate was able to be oxidized to Mn(III) acetate which was characterized by a color change to brown and had formed two phases as the end product of oxidative decarboxylation which was thought to contain hydrocarbons in the upper phase. Decarboxylation enzymes used by some microbes in their metabolism involve fatty acids and their active sites consist of cofactors in the form of heme or Fe metal, thus indicating the potential of Fe as an alternative catalyst for fatty acid decarboxylation at low temperatures text |
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Teknik tertentu, alat, perlengkapan, materi |
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Teknik tertentu, alat, perlengkapan, materi Hendrik DECARBOXYLATION (OXIDATIVE) SATURATED FATTY ACIDS TO BIOHYDROCARBONS AT LOW TEMPERATURES |
| description |
Indonesia has been a net importer of crude oil plus petroleum fuels since 2004. With the
gradually declining domestic crude oil production, whereas the need for fuel continues to
increase along with the country's economic growth, the counytry’s import of petroleum
fuels plus crude oil increases year after year. Therefore, for the sake of national energy
security, Indonesia needs to be able to produce alternative fuels within the country. The
study of the Gibbs free energy changes of C12 to C16 fatty acids decarboxylation
reactions into bioalkanes or bioalkenes with one less carbon atoms than the original fatty
acids showed that the reactions are thermodynamically feasible and could achieve
complete conversion, even at room temperature. Further literature study showed that
manganese(II) acetate have the potential to become catalyst for the autoxidative
decarboxylation of these fatty acids. The objective of proposed research is to either prove
or disprove the potential of the catalyst candidate. In this study, Mn(II) acetate was able
to be oxidized to Mn(III) acetate which was characterized by a color change to brown and
had formed two phases as the end product of oxidative decarboxylation which was
thought to contain hydrocarbons in the upper phase. Decarboxylation enzymes used by
some microbes in their metabolism involve fatty acids and their active sites consist of
cofactors in the form of heme or Fe metal, thus indicating the potential of Fe as an
alternative catalyst for fatty acid decarboxylation at low temperatures |
| format |
Final Project |
| author |
Hendrik |
| author_facet |
Hendrik |
| author_sort |
Hendrik |
| title |
DECARBOXYLATION (OXIDATIVE) SATURATED FATTY ACIDS TO BIOHYDROCARBONS AT LOW TEMPERATURES |
| title_short |
DECARBOXYLATION (OXIDATIVE) SATURATED FATTY ACIDS TO BIOHYDROCARBONS AT LOW TEMPERATURES |
| title_full |
DECARBOXYLATION (OXIDATIVE) SATURATED FATTY ACIDS TO BIOHYDROCARBONS AT LOW TEMPERATURES |
| title_fullStr |
DECARBOXYLATION (OXIDATIVE) SATURATED FATTY ACIDS TO BIOHYDROCARBONS AT LOW TEMPERATURES |
| title_full_unstemmed |
DECARBOXYLATION (OXIDATIVE) SATURATED FATTY ACIDS TO BIOHYDROCARBONS AT LOW TEMPERATURES |
| title_sort |
decarboxylation (oxidative) saturated fatty acids to biohydrocarbons at low temperatures |
| url |
https://digilib.itb.ac.id/gdl/view/76302 |
| _version_ |
1822994807987896320 |