Frontiers of Chemical Science and Engineering >
Pd nano-catalyst supported on biowaste-derived porous nanofibrous carbon microspheres for efficient catalysis
Received date: 21 Aug 2022
Accepted date: 27 Dec 2022
Published date: 15 Sep 2023
Copyright
Environmental pollution caused by the presence of aromatic aldehydes and dyes in wastewater is a serious global concern. An effective strategy for the removal of these pollutants is their catalytic conversion, possibly to valuable compounds. Therefore, the design of efficient, stable and long-lifetime catalysts is a worthwhile research goal. Herein, we used nanofibrous carbon microspheres (NCM) derived from the carbohydrate chitin present in seafood waste, and characterized by interconnected nanofibrous networks and N/O-containing groups, as carriers for the manufacture of a highly dispersed, efficient and stable Pd nano-catalyst (mean diameter ca. 2.52 nm). Importantly, the carbonised chitin’s graphitized structure, defect presence and large surface area could promote the transport of electrons between NCM and Pd, thereby endowing NCM supported Pd catalyst with high catalytic activity. The NCM supported Pd catalyst was employed in the degradation of some representative dyes and the chemoselective hydrogenation of aromatic aldehydes; this species exhibited excellent catalytic activity and stability, as well as applicability to a broad range of aromatic aldehydes, suggesting its potential use in green industrial catalysis.
Key words: biowaste chitin; nanofibrous; palladium; nano-catalyst; catalysis
Xianglin Pei , Siyu Long , Lingyu Zhang , Zhuoyue Liu , Wei Gong , Aiwen Lei , Dongdong Ye . Pd nano-catalyst supported on biowaste-derived porous nanofibrous carbon microspheres for efficient catalysis[J]. Frontiers of Chemical Science and Engineering, 2023 , 17(9) : 1289 -1300 . DOI: 10.1007/s11705-023-2299-7
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