What question did this study set out to answer?

This research aims to develop a method for the selective conversion of cellulose into C6-ketones using syngas, without the need for external acids or high-purity hydrogen.

March 7, 2026Open Access

Syngas-Promoted Selective Catalytic Hydrogenolysis of Cellulose into C6-Ketones

Key Points

This research aims to develop a method for the selective conversion of cellulose into C6-ketones using syngas, without the need for external acids or high-purity hydrogen.
Utilized a commercial Pd/C catalyst under optimal conditions of 230 °C and 3.0 MPa total pressure.
Explored the dual promotional effects of carbon monoxide in the reaction mechanism.
Conducted mechanistic studies on competitive adsorption and in-situ carbonic acid generation.
Achieved a yield of 37.8 C-mol% C6-ketones, a 6.8-fold enhancement over using pure hydrogen.
Demonstrated that CO suppresses excessive hydrogenation by competitive adsorption on Pd.
Proved that CO participates in the water-gas shift reaction, generating in-situ carbonic acid to facilitate ketone formation.

Abstract

Selective hydrogenolysis of cellulose into C 6 -ketones offers a promising route for the production of high-value carbonyl compounds. However, conventional metal-catalyzed hydrogenolysis methods typically rely on externally added acids and require high-purity H 2 . Herein, we report an alternative syngas-promoted hydrogenolysis method that eliminates these dual dependencies while enabling the selective transformation of cellulose into value-added C 6 -ketones. Under optimal conditions, using a commercial Pd/C catalyst at 230 °C and 3.0 MPa total pressure (H 2 /CO = 1.5/1.5 MPa) for 2 h, the yield of C 6 -ketones reached 37.8 C-mol%, representing a 6.8-fold enhancement compared to that obtained under pure H 2 . Mechanistic studies demonstrated a dual promotional effect of CO in directing cellulose to C 6 -ketones. First, competitive adsorption of CO on Pd active sites suppresses excessive hydrogenation and undesired hydrogenolysis of cellulose-derived intermediates. Second, CO participates in the water–gas shift (WGS) reaction (CO + H 2 O ⇌ CO 2 + H 2 ), generating carbonic acid (H 2 CO 3 ) in-situ via CO 2 + H 2 O ⇌ H 2 CO 3 , which provides a controllable acidic environment that promotes key intermediate transformations associated with C 6 -ketone precursor formation. Syngas (H 2 /CO) promotes selective hydrogenolysis of cellulose to C 6 -ketones (37.8 C-mol% yield) over a Pd/C catalyst, eliminating the need for external acid or pure H 2 . CO competitively adsorbs on Pd, suppressing over-hydrogenation, and generates in-situ H 2 CO 3 via the WGS reaction to provide an acidic environment for ketone formation. • A syngas-promoted strategy enables selective hydrogenolysis of cellulose into C 6 -ketones over commercial Pd/C without external acids. • Optimal H 2 /CO pressure yields 37.8 C-mol% C 6 -ketones, demonstrating a 6.8-fold enhancement over pure H 2 . • CO plays a dual role by in-situ generating carbonic acid via water-gas shift reaction and suppressing excessive hydrogenation through competitive adsorption.

Syngas-Promoted Selective Catalytic Hydrogenolysis of Cellulose into C6-Ketones

Key Points

Abstract

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