Abstract
Meeting the transport needs of a growing world population makes it imperative to develop renewable and sustainable routes to production of liquid fuels. With a market-driven economic structure and pressing environmental issues, it is essential that these new routes provide environmental benefits while being economically viable. Conversion of second-generation lignocellulosic biomass resources to fuels via pyrolysis represents an important technological route. In this article, we report comparative assessment of the economic and lifecycle environmental aspects for catalytic and thermal pyrolysis. The goal of this assessment is two-fold: one is to understand the potential of this conversion route via the catalytic and thermal processes and second is to provide feedback for further development of catalysts for various stages of this conversion. The complete assessment is interdisciplinary in nature and connects the laboratory experiments with contextual sustainability assessment. Three catalytic and one thermal pyrolysis processes are analyzed using this assessment approach. Subject to the model choices and data inputs, the results, which consider quality of the oil product, show that biofuels produced using catalytic and thermal routes are rather expensive compared to gasoline. But at the same time, they provide significant greenhouse gas emission savings and can lead to lower CO2 abatement costs compared to the first-generation ethanol that is used currently. With one of the product scenarios of hydrotreated (HT) oil, the abatements costs are estimated to be 51% of those associated with first-generation ethanol. Additional product scenarios with developments in catalysts show potential to further reduce abatement costs significantly to below 100 EUR per metric tonne of CO2 equivalents. Using scenario analysis, the results help us to understand specific areas for development of novel catalysts. At the same time, the results demonstrate the trade-offs associated with the variety and complexity of technical factors associated with the pyrolysis routes. The study highlights the challenges and the promises of catalytic and thermal pyrolysis for production of high-quality biofuels produced via a sustainable production route.
Highlights
Access to efficient mobility is an important need for billions of people all over the world, and freight of goods has been increasing very substantially parallel to the process of globalization
The results are presented in detail for the biofuel produced using the Cs/ASA catalyst and complete hydro-treating to reach 3.7% oxygen content in the final fuel product (HT_Oil_Cs/ASA)
The cost for the combined heat and and power generation (CHP) section includes the combustor, which is used as catalyst regenerator unit for catalytic pyrolysis
Summary
Access to efficient mobility is an important need for billions of people all over the world, and freight of goods has been increasing very substantially parallel to the process of globalization Both person mobility and freight are cornerstones of economic activity and thereby improve quality of life. The finite nature of fossil resources puts a question mark on their future availability and ability to provide affordable fuels. In addition to this uncertainty, the use of fossil-resource-based transport fuels is responsible for negative environmental impacts such as climate change due to greenhouse gas emissions, species destruction due to global warming, ocean acidification, and oil spills. Apart from the biofuel, the plant has been modeled to produce hydrogen, electricity, steam, heat.
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