Biodiesel (Methyl Esters)
Abstract
Biodiesel, an environmentally friendly biomass-based fuel, is gaining popularity globally as a
cost-effective way to meet rising fuel demand. However, the high cost of raw materials and
catalysts continues to drive up biodiesel production. An alternative feedstock with a
heterogeneously catalyzed reaction could be the most cost-effective way to stabilize industrial
biodiesel growth. Understanding these issues led to the idea of using waste palm oil as a
feedstock for biodiesel production. While using waste materials as feedstock for biodiesel is an
elegant solution, converting high free fatty acids (FFA) directly into methyl esters has some
drawbacks. High FFA processes (acid esterification, then base transesterification) are costly.
The commercial processes currently use a homogeneous system with sulfuric acid to catalyze
both esterification and transesterification. However, heterogeneous solid acid catalysts are
preferred over hazardous mineral acids for high FFA esterification because they are less
corrosive, produce less waste, and are easier to separate from reactants and products by
filtration, recovery, and reusability. Heterogeneous acid catalysts can also simultaneously
catalyze transesterification and esterification reactions. Thus, new waste-based support for
heterogeneous catalysts (solid acid catalysts) is required to convert waste oils into biodiesel.