Nanocatalysts in Biodiesel Production: Advancements, Challenges, and Sustainable Solutions

Abstract

The application of nanocatalysts for the conversion of crude oil into biodiesel represents a promising strategy to mitigate environmental issues and diminish dependence on fossil fuels. This review scrutinizes contemporary developments in nanocatalyst technology pertaining to biodiesel synthesis, emphasizing the effectiveness, specificity, and ecological sustainability of various nanocatalysts, which include metal oxides, magnetic solid catalysts, and an array of other nanostructured materials. These catalysts have exhibited substantial potential in augmenting the efficiency and selectivity of biodiesel production, attributable to their enhanced catalytic performance, extensive surface area, and resilience to saponification, rendering them appropriate for diverse feedstocks such as recycled oils, animal fats, and plant oils. Notwithstanding the obstacles associated with production costs and recycling procedures, recent progress in economically viable manufacturing techniques and sustainable recovery methods, including magnetic separation approaches, offers significant promise. A thorough lifecycle assessment (LCA) remains imperative to appraise the environmental and economic viability of employing nanocatalysts, taking into account parameters, such as raw material acquisition, energy utilization, and waste generation. The review accentuates the superior efficacy of nanocatalysts in comparison to traditional heterogeneous catalysts, underscoring their capacity to expedite biodiesel synthesis and facilitate a transition toward a more environmentally sustainable energy paradigm.