Sustainable aviation fuels from biomass and biowaste via bio- and chemo-catalytic conversion: Catalysis, process challenges, and opportunities
Junyan Zhang, Matthew S. Webber, Yunqiao Pu, Zhenglong Li, Xianzhi Meng, Michael L. Stone, Bingqing Wei, Xueqi Wang, Sainan Yuan, Bruno Colling Klein, Bhogeswararao Seemala, Charles E. Wyman, Karthikeyan Ramasamy, Mike Thorson, Matthew Langholtz, Joshua S. Heyne, Aibolat Koishybay, Shiba P. Adhikari, Sufeng Cao, Andrew D. Sutton, Gerald A. Tuskan, Yuriy Román‐Leshkov, Arthur J. Ragauskas, Ling Tao, Brian H. Davison
Abstract
Sustainable aviation fuel (SAF) production from biomass and biowaste streams is an attractive option for decarbonizing the aviation sector, one of the most-difficult-to-electrify transportation sectors. Despite ongoing commercialization efforts using ASTM-certified pathways (e.g., lipid conversion, Fischer–Tropsch synthesis), production capacities are still inadequate due to limited feedstock supply and high production costs. New conversion technologies that utilize lignocellulosic feedstocks are needed to meet these challenges and satisfy the rapidly growing market. Combining bio- and chemo-catalytic approaches can leverage advantages from both methods, i.e., high product selectivity via biological conversion, and the capability to build C-C chains more efficiently via chemical catalysis. Herein, conversion routes, catalysis, and processes for such pathways are discussed, while key challenges and meaningful R&D opportunities are identified to guide future research activities in the space. Bio- and chemo-catalytic conversion primarily utilize the carbohydrate fraction of lignocellulose, leaving lignin as a waste product. This makes lignin conversion to SAF critical in order to utilize whole biomass, thereby lowering overall production costs while maximizing carbon efficiencies. Thus, lignin valorization strategies are also reviewed herein with vital research areas identified, such as facile lignin depolymerization approaches, highly integrated conversion systems, novel process configurations, and catalysts for the selective cleavage of aryl C–O bonds. The potential efficiency improvements available via integrated conversion steps, such as combined biological and chemo-catalytic routes, along with the use of different parallel pathways, are identified as key to producing all components of a cost-effective, 100% SAF. Lignin-first approach followed by hydrodeoxygenation is used to produce SAF. Bio- and chemo-catalytic conversion pathways utilize the carbohydrate fraction of lignocellulose for SAF production. These parallel pathways offer great potential to producing all components of a cost-effective, 100% SAF. • Hybrid bio- and chemo-catalytic conversion pathways are reviewed for sustainable aviation fuel production from biomass. • Lignin valorization strategies are discussed with vital research areas identified. • Conversion routes, catalysis, and processes are discussed, while key challenges and R&D opportunities are identified.