木质素
材料科学
原材料
催化作用
解聚
单体
脱氢
化学工程
纤维素乙醇
碳纤维
键裂
有机化学
水解
产量(工程)
航空燃料
乙醚
生物炼制
硼
再分配(选举)
作者
Nan Wang,Zhijie Liao,Yaxin Deng,Qiyu Liu,Xuliang Lin,Yanlin Qin,Xueqing Qiu
摘要
ABSTRACT Technical lignin valorization is fundamentally limited by the scarcity and kinetic inertia of cleavable C─O linkages in a condensed C─C/C─O network, constraining the production of aromatic monomers and other fuel‐relevant intermediates. Here, we report a coordination‐engineered Ni‐Pd on lignin‐derived Carbon (NiPd 0.1 /C) constructed via solvent/antisolvent assembly to enable trace Pd incorporation that electronically modulates Ni. Structural analyses suggest a uniform solid solution with interfacial charge redistribution (Ni δ+ ‐Pd δ− ), which generates polarized interfacial sites and strengthens C─O bond activation. The NiPd 0.1 /C boosts aromatic monomer yield from enzymatic hydrolysis lignin to 23 wt.%, outperforming commercial Pd/C (∼16 wt.%). Product analysis shows syringyl/guaiacyl/p‐hydroxyphenyl (S/G/H)phenolics dominated by G‐type units, and the catalyst remains effective for more condensed alkali lignin (∼16 wt.% monomers), underscoring feedstock tolerance. Model‐compound and kinetic studies indicate that Ni‐Pd alloying accelerates the turnover of phenoxy intermediates by lowering the apparent barrier for dehydrogenation and subsequent ether C─O bond cleavage, thereby enabling the selective cleavage of C─O bonds. This work establishes solid‐solution electronic engineering as a broadly generalizable strategy to unlock cost‐effective C─O activation and accelerate lignin valorization toward scalable, low‐carbon aviation fuel precursors.
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