Journal of Textile Research ›› 2021, Vol. 42 ›› Issue (07): 175-183.doi: 10.13475/j.fzxb.20200607109

• Comprehensive Review • Previous Articles     Next Articles

Recent progress in preparation of cellulose-based organic-inorganic photocatalysts nanohybrids and it's application in water treatment

ZHANG Tingting1,2,3, XU Kexin1, JIN Mengtian2,3, GE Shijie2,3, GAO Guohong4, CAI Yixiao1,2,3(), WANG Huaping2,3   

  1. 1. College of Environmental Science and Engineering, Donghua University, Shanghai 201620, China
    2. College of Materials Science and Engineering, Donghua University, Shanghai 201620, China
    3. State Key Laboratory for Modification of Chemical Fibers and Polymer Materials, Donghua University, Shanghai 201620, China
    4. Jiangsu Guowang High-Tech Fiber Co., Ltd., Suzhou, Jiangsu 215226, China
  • Received:2020-06-30 Revised:2021-01-08 Online:2021-07-15 Published:2021-07-22
  • Contact: CAI Yixiao E-mail:yxcai@dhu.edu.cn

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Abstract:

With the aim of solving the agglomeration of traditional nano-sized photocatalysts particles that leads to low catalytic activity and recycling difficulty, it is imperative to promote the scalable application of advanced photocatalytic technology using cellulose based hybrid photocatalysts with high active site exposure, high dispersion and long-term stability. This review summarizes the recent progress in worldwide research on cellulose-based organic-inorganic photocatalysts nanohybrids. In terms of different cellulose forms, the fabrication and preparation principle of nanocellulose, cellulose-based membrane, cellulose-based aerogel and their application in the fields of water treatment are discussed. The prospect of cellulose based photocatalytic materials and the existing scientific questions and limitations are proposed. It is anticipated that this review can be used as a reference for preparation and industrialization of cellulose-based functional materials, especially in areas of environmental remediation.

Key words: cellulose-based functional material, environmental remediation, organic-inorganic nanohybrid, advanced oxidation technology, dyeing and printing wastewater treatment

CLC Number: 

  • TS102.5

Tab.1

Classification of nanocellulose and preparation method"

名称 制备方法 直径/nm 长度/nm 聚合度
CNF 机械法、
TEMPO氧化法 		5~60 1 000~10 000 ≥500
CNC 酸水解法 5~70 100~250 500~15 000
BC 细菌合成法 20~100 呈纤维网络结构 4 000~10 000

Tab.2

Semiconductor/cellulose composites for degradation of organic pollutants"

光催化材料 制备形态 污染物 光源(波长) 降解率/% 时间/min 参考文献
TiO2/C/棉纤维素 纳米纤维 X-BR 紫外光 90.0 15 [31]
GO@TiO2/纤维素 纳米纤维 IC
MB 		40 W紫外光 (320~400 nm) 99.8
98.3 		150
250 		[32]
C掺杂 ZnO/纤维素 纳米颗粒 MO 6 W (200~400 nm) 95.4 120 [33]
ZIF-8/CNC 纳米颗粒 MB 太阳光 99.8 300 [34]
ZnO/CuO/CNC 纳米颗粒 RB 20 W 紫外光 99.7 40 [35]
BiOBr/纤维素微晶 纳米颗粒 RhB 300 W氙灯(>420 nm) 90.0 70 [36]
g-C3N4/CA RhB 太阳光 99.0 150 [37]
TiO2-Au/纤维素 RhB 500 W氙灯(>400 nm) 94.99 300 [38]
H4SiW12O40/CA MO 300 W 汞灯 94.6 120 [39]
TiO2/PDA/BC MO
RhB
MB 		500 W汞灯(>320 nm) 95.1
100.0
99.5 		30
60
20 		[40]
g-C3N4/纤维素 气凝胶 MB 350 W氙灯(>400 nm) 99.8 80 [41]
TiO2/ CNF 气凝胶 MB 汞灯(365 nm) 98.1 20 [42]
Cu2O/CBA 气凝胶 MB 350 W氙灯(>400 nm) 95.79 60 [43]
CuS/CBA 气凝胶 MB 500 W氙灯(>400 nm) 94.1 60 [44]
SiO2-WxTiO2/纤维素 气凝胶 RhB 125 W汞灯(>400 nm) 95.0 120 [45]
β-FeOOH/纤维素 水凝胶 MB 300 W氙灯(>420 nm) 99.89 30 [46]

Tab.3

Semiconductor/cellulose composites for removal of heavy metal ions"

光催化材料 制备形态 污染物 光源 去除率/% 时间/min 参考文献
P25/CAM 一体式 Cr6+ 1700 W氙弧灯(280~400 nm) 100 90 [49]
TiO2/CNC 纳米颗粒 Cr6+ 300 W氙弧灯(420 nm) 96 80 [50]
N掺杂C/纤维素 纳米颗粒 Cr6+ 500 W氙灯(>420 nm) 80 300 [51]
ZnIn2S4/CNF 纳米颗粒 Cr6+ 300 W氙灯(>420 nm) 100 90 [12]
BiOBr/CCNF 纳米颗粒 Cr6+ 200 W LED灯 100 60 [52]
SWCNT/Fe3O4/TiO2/壳聚糖/CA 纳米纤维 As5+和Cr6+ 30 W UV灯(365 nm) >95 60 [53]
g-C3N4/CA 薄膜 Cr6+ 300 W氙灯(380~750 nm) 95 100 [37]
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