Journal of Textile Research ›› 2025, Vol. 46 ›› Issue (06): 151-159.doi: 10.13475/j.fzxb.20241103201

• Dyeing and Finishing Engineering • Previous Articles     Next Articles

Yak wool decolorization using homogeneous advanced oxidation technology and its mechanism

WEI Xuanxiang1,2, FENG Yang1,2, FAN Xiangyu3, WU Minghua1,2, YU Deyou1,2()   

  1. 1. State Key Laboratory of Bio-based Fiber Materials, Zhejiang Sci-Tech University, Hangzhou, Zhejiang 310018, China
    2. Engineering Research Center of Ecological Dyeing and Finishing Technology (Ministry of Education), Zhejiang Sci-Tech University, Hangzhou, Zhejiang 310018, China
    3. EP Yaying Fashion Group Co., Ltd., Jiaxing, Zhejiang 314000, China
  • Received:2024-11-13 Revised:2025-03-10 Online:2025-06-15 Published:2025-07-02
  • Contact: YU Deyou E-mail:yudeyou92@zstu.edu.cn

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Abstract:

Objective The yak wool fibers are inherent in colors primarily including black, purple and brown, failing to meet the demand for multi-color varieties for applications. Hence, the fibers need to be bleached prior to dyeing with target colors. However, the traditional bleaching process has limitations in oxidant selection and elusive mechanism remained in conventional yak wool decolorization. Herein, the bleaching capacity and environmental impact of homogeneous advanced oxidation processes with three typical oxidants were compared. Meanwhile, the mechanism of hydrogen peroxide(H2O2)-driven efficient decolorization was also investigated.

Method Inspired by the homogeneous advanced oxidation technology for organic pollutants degradation, a comparative study was conducted to examine the effects of three typical oxidants H2O2, peracetic acid (PAA), and potassium peroxymonosulfate (PMS) on decolorization of yak wool fibers using ferrous sulfate as the catalyst. Using the whiteness index and breaking strength as evaluation indicators, the most suitable oxidant was identified and the decolorization parameters were optimized. The reactive oxygen species were identified and analyzed using the electron spin resonance(EPR) technology and quenching experiment. Finally, the environmental impact of the decolorization process was assessed via the life cycle assessment (LCA).

Results The results of single-factor experiments indicated that hydrogen peroxide is the most suitable green oxidizing agent for decolorizing yak wool. The optimal decolorization conditions were determined to be an H2O2 concentration of 25 g/L, a temperature of 60 ℃, and a solution pH value of 8.5. Under these conditions, the whiteness of yak wool fibers reached up to 68%, with a fiber breaking strength loss of approximately 12%. Mechanistic analysis of the H2O2 decolorization process revealed the presence of hydroxyl radicals (·OH) and singlet oxygen (1O2) in the system. Further quenching experiments demonstrated that ·OH and 1O2 are the main reactive oxygen species responsible for decolorization, with ·OH playing the primary role and 1O2 having a secondary effect. Scanning electron microscope images revealed that yak wool fibers treated with H2O2 or PAA for decolorization exhibited surface damage, including roughened cuticle scales and unclear scale edges. Fibers treated with PMS showed even more severe damage, with cuticle scales becoming indistinct or completely detached in some areas. LCA results showed that the PMS decolorization process had the highest environmental impacts on global warming potential, terrestrial ecotoxicity, non-carcinogenic human toxicity, and fossil resource scarcity, while both PMS and PAA decolorization processes had significant negative impacts on environmental ecology and human health. Therefore, compared to the other two oxidants, decolorization using H2O2 was more environmental-friendly and low-carbon.

Conclusion Inspired by the advantages of the homogeneous advanced oxidation technology for organic pollutants degradation, three typical oxidants including hydrogen peroxide, peracetic acid, and hydrogen persulfate were screened and compared for yak wool fiber decolorization using ferrous sulfate as the catalyst. The results revealed that hydrogen peroxide is the most suitable oxidizing agent for practice. The optimal decolorization condition was identified to be H2O2 concentration of 25 g/L, temperature of 60 ℃, and solution pH value of 8.5. After being decolorized by hydrogen peroxide, the whiteness of yak wool fibers reached 68%, and the loss of strength was relatively small. The decolorization mechanism of hydrogen peroxide bleaching system showed that both the hydroxyl radical and singlet oxygen contributed to the yak wool fiber decolorization, in which hydroxyl radical played the primary role and singlet oxygen served a secondary function. Life cycle assessment showed that, compared to PMS and peracetic acid, the use of H2O2 for decolorization had the lowest environmental impact, which aligns better with the green and low-carbon development trend for yak wool decolorization processes.

Key words: yak wool, decolorization oxidant, hydrogen peroxide, life cycle assessment, homogeneous advanced oxidation, decolorization

CLC Number: 

  • TS192.5

Fig.1

Whiteness and breaking strength of yak wool at different hydrogen peroxide concentrations"

Fig.2

Whiteness and breaking strength of yak wool at different decoloration temperatures"

Fig.3

Whiteness and breaking strength of yak wool under different pH values"

Fig.4

Influence of mass concentrations of peracetic acid on whiteness and breaking strength of yak wool"

Fig.5

Influence of decolorization temperature on whiteness and breaking strength of yak wool"

Fig.6

Influence of decolorization pH values on whiteness and breaking strength of yak wool"

Tab.1

Length and shorting rate of yak wool decolored by optimum process"

组别 平均长度/mm 20 mm以下短绒率/%
原样 50.80 15.29
双氧水脱色 50.53 18.63
过氧乙酸脱色 50.69 17.38

Fig.7

EPR spectra of DMPO/·OH (a) and TEMP/1O2 (b) for ferrous ion pretreatment-hydrogen peroxide systems"

Fig.8

Influence of DMSO concentration (a) and furfuryl alcohol concentration (b) on decolorization of yak wool"

Fig.9

SEM images of yak wool decolorized by different oxidants. (a)Untreated sample;(b)H2O2 decolorized;(c)PAA decolorized;(d)PMS decolorized"

Tab.2

Influence of three oxidants bleaching on environmental"

影响类别 不同氧化剂漂白工艺的
18个环境指标影响程度
双氧水
漂白		 过氧乙
酸漂白		 过一硫酸
氢钾漂白		 单位
全球变暖 438.25 479.87 618.80 kg CO2 eq
平流层气流耗竭 0.00 0.00 0.00 kg CFC11 eq
电离辐射 7.21 8.06 14.94 kBq Co-60 eq
臭氧形成(人类健康) 1.22 1.32 1.61 kg NOx eq
细颗粒物形成 0.68 0.74 0.94 kg PM2.5 eq
臭氧形成(陆地生态系统) 1.22 1.33 1.61 kg NOx eq
陆地酸化 1.52 1.68 2.09 kg SO2 eq
淡水富营养化 0.09 0.09 0.13 kg P eq
海洋富营养化 0.01 0.01 0.01 kg N eq
陆地生态毒性 398.15 432.72 617.96 kg 1,4-DCB
淡水生态毒性 13.95 15.12 18.62 kg 1,4-DCB
海洋生态毒性 17.77 19.27 23.90 kg 1,4-DCB
人类致癌毒性 13.72 14.86 18.60 kg 1,4-DCB
人类非致癌毒性 140.18 152.28 212.17 kg 1,4-DCB
土地使用 5.42 5.88 7.75 m2·a crop eq
矿产资源稀缺 0.26 0.28 0.44 kg Cu eq
化石资源稀缺 86.41 95.34 129.21 kg oil eq
水资源消耗 1.37 1.51 2.13 m3

Fig.10

Normalized environmental impact of three oxidant bleaching processes"

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