Cell Reports Sustainability (Aug 2024)
Renewable indanone and thermal-stable aviation fuel from cellulose
Abstract
Summary: Indanone and its analogs are widely used intermediates for many useful chemicals. Decalin and its alkylated analogs are major components of thermal-stable aviation fuels and the additives used to improve the thermal stability of aviation fuel. In this work, we develop an integrated route to selectively produce trimethyl-indanone or alkylated decalin with cellulose. First, cellulose was hydrogenolyzed to 2,5-hexanedione in a biphasic reaction system of toluene/NH4Br aqueous solution over Pd/C catalyst. Under the catalysis of alkali hydroxide, 2,5-hexanedione was converted to a mixture of C12 oxygenates (with trimethyl-indanone as the main component) at room temperature. Trimethyl-indanone can be used as an intermediate for many useful chemicals. Moreover, the C12 oxygenates can be hydrodeoxygenated to a mixture of dimethyl decalin and C12 monocycloalkanes with a low freezing point (200 K) and high density (0.85 g mL−1). This work provides insights on the preparation of indanone or advanced aviation fuel with cellulose. Science for society: The production of valuable chemicals and sustainable aviation fuel (SAF) with renewable, cheap, and abundant lignocellulose has drawn a lot of attention. Indanone and its analogs are widely used as intermediates in the manufacture of many useful chemicals. Currently, these compounds are obtained from fossil resources at low yields. Decalin and alkylated decalins are additives to improve the thermal stability of aviation fuel. Herein, we report an integrated route for the selective preparation of trimethyl-indanone or alkylated decalins with cellulose, the most abundant biomass. Compared with the reported processes to produce indanone analogs or SAF, this new process has several advantages, such as renewable feedstock, mild reaction conditions, fewer steps, and excellent fuel properties (e.g., lower freezing point, higher volumetric heat value, thermal stability of final products, etc.). This work paves a new way for the high-value utilization of cellulose.
