Journal of Textile Research ›› 2025, Vol. 46 ›› Issue (11): 170-177.doi: 10.13475/j.fzxb.20241206901

• Dyeing and Finishing Engineering • Previous Articles     Next Articles

Influence of precursor form on electrocatalytic properties of silk fibroin-based carbon materials

FENG Yatong, JIANG Yueyao, WANG Ping(), ZHANG Yan   

  1. College of Textile and Clothing Engineering, Soochow University, Suzhou, Jiangsu 215021, China
  • Received:2024-12-30 Revised:2025-07-10 Online:2025-11-15 Published:2025-11-15
  • Contact: WANG Ping E-mail:pingwang@suda.edu.cn

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Abstract:

Objective This study aims to investigate the influence of different silk fibroin precursors (woven fabric (F-P), natural cocoon (C-P), degummed silk (D-P), regenerated film (R-P) on catalyst structure and hydrogen evolution reaction (HER) performance. In order to address the issure of textile waste valorization, this research clarifies how precursor morphology regulates metal loading behavior and carbon matrix defects, as an attempt to provide theoretical basis for designing high-performance textile-based electrocatalysts.
Method Silk fabric-derived catalyst (F-C), cocoon-derived catalyst (C-C), degummed silk fibroin-derived catalyst scanning electron microscopy and regenerated film-derived catalyst (R-C) were prepared from silk precursors by KCl activation, Co salt impregnation, and carbonization/sulfidation. Morphology was observed by scanning electron microscopy (SEM), and composition and structure were analyzed by Raman spectroscopy, Fourier transform infrared spectroscopy (FT-IR), X-ray diffraction(XRD). Hydrogen evolution reaction (HER) performance was evaluated via double-layer capacitance (Cdl), linear sweep volta mmetry (LSV) polarization curves, Tafel slopes, and electrochemical impedance spectroscopy (EIS) in 0.5 mol/L H2SO4 electrolyte.
Results Different forms of precursors exhibited different surface structure characteristics before and after carbonization. The microscopic morphology of the precursor was found to affect the growth of metal sulfides during the impregnation process, with various shapes such as needle-like bouquets, flower buds blocks, strips, and uneven loading. Different forms of precursors formed Co3S4 spinel sulfide as the main active component on the surface of the impregnated loaded metal, and the main body of the precursor was transformed into a carbon skeleton after carbonization. The chemical composition of the catalyst materials was basically the same, but with different defect structures and degrees of graphitization, among which the degummed silk fibroin-derived sample D-C showed the highest degree of graphitization. Silk fibroin-based carbon materials exhibited excellent electrocatalytic activity in HER electrocatalysis, but differences exist in Tafel slope and impedance, etc. In general, the catalyst D-C derived from degumming silk fibroin as a carbon precursor demonstrated the best electrocatalytic activity, and the overpotential η10 value was only 235 mV.
Conclusion The loose and smooth degummed silk fibroin fibers significantly enhance activation efficiency and metal loading density, enabling D-C catalysts to achieve high surface area, graphitization, and abundant Co3S4active sites for superior HER performance. This study confirms precursor morphology as a key factor in regulating textile-based electrocatalysts, offering a novel approach for silk waste valorization.

Key words: precursor, silk fibroin-based carbon material, hydrogen evolution reaction, silk, electro-catalytic property, catalyst, carbonization

CLC Number: 

  • TQ116.2

Fig.1

Preparation flow process of catalyst samples"

Fig.2

SEM images of different silk fibroin-based carbon material precursors"

Fig.3

SEM images of catalyst derived from different precursors"

Fig.4

Raman spectra of different silk fibroin-based carbon material precursors (a) and catalysts (b)"

Tab.1

Raman peak positions and ID/IG ratios of different silk fibroin-based catalysts"

样品名称 D峰位置/cm-1 G峰位置/cm-1 ID/IG
F-C 1 347.58 1 577.72 0.996
R-C 1 337.28 1 577.76 1.006
C-C 1 350.30 1 582.98 0.984
D-C 1 349.16 1 566.18 0.956

Fig.5

Infrared spectra of precursors (a) and catalysts (b) of different silk fibroin-based carbon materials"

Fig.6

XRD patterns of precursors (a) and catalysts (b) of different silk fibroin-based carbon materials"

Fig.7

Electrochemical properties of catalyst. (a) Electric double-layer capacitance Cdl value; (b) Polarization curves;(c) Tafel slopes; (d) Electrochemical impedance EIS Nernst spectra"

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