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全氟辛酸光催化材料应用及降解机理研究进展

魏健 徐晓月 郭壮 段丽杰 宋永会

魏健,徐晓月,郭壮,等.全氟辛酸光催化材料应用及降解机理研究进展[J].环境工程技术学报,2023,13(3):1127-1138 doi: 10.12153/j.issn.1674-991X.20220573
引用本文: 魏健,徐晓月,郭壮,等.全氟辛酸光催化材料应用及降解机理研究进展[J].环境工程技术学报,2023,13(3):1127-1138 doi: 10.12153/j.issn.1674-991X.20220573
WEI J,XU X Y,GUO Z,et al.Research progress in the application and degradation mechanism of perfluorooctanoic acid photocatalytic materials[J].Journal of Environmental Engineering Technology,2023,13(3):1127-1138 doi: 10.12153/j.issn.1674-991X.20220573
Citation: WEI J,XU X Y,GUO Z,et al.Research progress in the application and degradation mechanism of perfluorooctanoic acid photocatalytic materials[J].Journal of Environmental Engineering Technology,2023,13(3):1127-1138 doi: 10.12153/j.issn.1674-991X.20220573

全氟辛酸光催化材料应用及降解机理研究进展

doi: 10.12153/j.issn.1674-991X.20220573
基金项目: 国家重点研发计划重点专项(2021YFC3201505-04)
详细信息
    作者简介:

    魏健(1983—),男,副研究员,博士,主要从事水污染控制技术研究,weijian0911@163.com

    通讯作者:

    徐晓月(1998—),女,硕士研究生,主要从事水污染控制技术研究,xuxiaoyue0227@163.com

    宋永会(1967—),男,研究员,博士,主要从事水污染控制与流域治理技术研究,songyh@craes.org.cn

  • 中图分类号: X505

Research progress in the application and degradation mechanism of perfluorooctanoic acid photocatalytic materials

  • 摘要:

    全氟辛酸(PFOA)是一种广泛存在于环境介质中的典型全氟化合物,具有高毒性、难降解等特点,严重威胁生态环境安全及人类遗传、免疫、神经和生殖健康,其环境危害和风险防控引起广泛关注。光催化技术具有反应条件温和、处理效率高、应用成本低且无二次污染等优势,在PFOA的降解处理方面具有广阔应用前景。为研发活性强、可见光吸收性能好、稳定性高的新型光催化材料,实现水中PFOA的高效降解,系统梳理了近20年来PFOA光催化降解材料制备的相关研究,对不同光催化降解材料的降解特性及存在问题进行全面分析;结合现有材料对PFOA的光催化降解,总结光催化降解材料的反应机理及活性增强机制,阐明PFOA的光催化降解路径。

     

  • 图  1  PFOA分子结构

    Figure  1.  The molecular structure of PFOA

    图  2  光催化一般机理

    Figure  2.  General mechanism of photocatalysis

    图  3  传统光响应异质结光催化剂下几种不同类型的电子-空穴对分离示意

    Figure  3.  Schematic diagram of separation of several different types of electron-hole pairs under conventional photoresponsive heterojunction photocatalysts

    图  4  PFOA的光催化降解机制

    Figure  4.  Photocatalytic degradation mechanism of PFOA

    表  1  TiO2基材料对PFOA的光催化降解效果

    Table  1.   Photocatalytic degradation effect of PFOA by TiO2-based materials

    降解材料光类型光波长/nm光强度/W反应条件反应时
    间/h
    降解
    率/%
    脱氟
    率/%
    TiO2[20]UV310~40075V=50 mL,C0=1.5 mmol/L,pH=1.0,Ccat=2 g/L2447
    TNTs[37]UV254400V=2 L,C0=50 mg/L,pH=4.0,Ccat=0.125 g/L2459
    掺杂金属Pb-TiO2[13]UV254400C0=50 mg/L,pH=5.0,Ccatalyst=0.5 g/L1299.922.4
    Pt-TiO2[38]UV365125V=120 mL,C0=60 mg/L,pH=3.0,Ccat=0.5 g/L710034.8
    Cu-TiO2[26]UV254400C0=50 mg/L,pH=5.0,Ccat=0.5 g/L129119
    负载碳材料TiO2-MWCNTs(10:1)[30]UV365300V=250 mL,C0=30 mg/L,pH=2.0,Ccat=1.6 g/L894
    rGO-TiO2[32]UV或可见光200~600150C0=0.24 mmol/L,pH=3.8,Ccat=0.1 g/L1293±762
    构建异质结Fe/TNTs@AC[34]UV25430V=40 mL,C0=100 mg/L,pH=7.0,Ccat=1.0 g/L4>9062
    Sb2O3-TiO2[35]UV200~2804C0=10 mg/L,pH=4.4,Ccat=0.25 g/L281.7
    Ce/TiO2/g-C3N4[24]可见光420~800300C0=4 mg/L,pH=2.0,Ccat=1.0 g/L394.438.6
    Ti3C2/TiO2[39]UV2544.5C0=20 μmol/L,Ccat=0.2 g/L16>99.949.0
      注:—表示文献中未提及。V为反应体系容积;C0为PFOA初始浓度;pH为反应最佳条件下pH;Ccat为反应最佳条件下催化剂用量。
    下载: 导出CSV

    表  2  In2O3基材料对PFOA的光催化降解效果

    Table  2.   Photocatalytic degradation effect of PFOA by In2O3-based materials

    降解材料光类型光波长/nm光强度/W反应条件反应时
    间/h
    降解
    率/%
    脱氟
    率/%
    In2O3[18]UV25423V=400 mL,C0=0.1 mmol/L,pH=3.8,Ccat=0.5 g/L483.166.3
    3%Pt/IONRs[49]UV254500V=200 mL,C0=200 mg/L,pH=1.85,Ccat=0.4 g/L198
    g-C3N4-In2O3[45]UV254500V=50 mL,C0=200 mg/L,Ccat=0.4 g/L91(1 h)96(3 h)
    In2O3-GR[46]UV25415V=100 mL,C0=30 mg/L,Ccat=0.4 g/L310060.9
    0.86%CeO2/In2O3[47]UV254500V=200 mL,pH=2.84,C0=100 mg/L,Ccat=0.4 g/L110053.3
    MnOx-In2O3[50]太阳光500V=50 mL,C0=50 mg/L,pH=3.8,Ccat=0.5 g/L399.817.4
      注:同表1
    下载: 导出CSV

    表  3  Bi基材料对PFOA的光催化降解效果

    Table  3.   Photocatalytic degradation effect of PFOA by Bi-based materials

    降解材料光类型光波长/nm光强度/W反应条件反应时
    间/h
    降解
    率/%
    脱氟
    率/%
    BiOX0.95BiOI-0.05Br[53]UV254300V=30 mL,C0=20 mg/L,Ccat=0.4 g/L296
    BiOI/Bi5O7I[64]模拟太阳光400~760800V=40 mL,pH=3.0,C0=15 mg/L,Ccat=0.5 g/L68060
    BiOCl[55]UV25410V=200 mL,pH=4.8,C0=0.02 mmol/L,Ccat=0.5 g/L2459.352.5
    BiOCl0.2I0.8[65]可见光420~700300V=100 mL,C0=50 μmol/L,Ccat=1 g/L665.56
    BiOCl/BiPO4[66]UV2542V=50 mL,C0=20 mg/L,Ccat=0.5 g/L45100
    Zn-AlLDHs-BiOCl[57]UV<35050V=200 mL,pH=2.0,C0=0.5 mg/L,Ccat=0.5 g/L690
    BFO0.5% rGO-Pb-BFO[63]UV2545V=80 mL,pH=2.0,C0=100 mg/L,Ccat=0.05~0.4 g/L869.637.6
    BiOHP9% BiOHP/CS[59]UV25418V=40 mL,pH=7.0,C0=0.2 mg/L,Ccat=1.0 g/L>90(1 h)32.5(4 h)
      注:同表1
    下载: 导出CSV

    表  4  其他类型材料对PFOA的光催化降解效果

    Table  4.   Photocatalytic degradation effect of PFOA by other types of materials

    降解材料光类型光波长/nm光强度/W反应条件反应时间/h降解率/%脱氟率/%
    Ga2O3商业UV25414V=150 mL,C0=500 μg/L,pH=4.8,Ccat=0.5 g/L338
    束状[22]100(45 min)61(3 h)
    InOOH[68]UV25418V=200 mL,C0=20 mg/L,Ccat=0.25 g/L383.4
    ZnOZnO[19]UV25428V=1 L,C0=100 mg/L,pH=3.1,Ccat=0.2 g/L418.2
    ZnO/rGO[78]太阳光V=100 mL,C0=100 mg/L,Ccat=1 g/L10090.91
    Bi5O7I-ZnO[79]可见光420~700500V=50 mL,pH=4.0,C0=1 mg/L,Ccat=0.5 g/L69152.2
    HPWHPW[23]UV254200V=22 mL,C0=1.35 mmol/L,Ccat=6.68 mmol/L2410088
    HPW-BPS[71]UV1858V=500 mL,pH=3.0-4.0,C0=5 mg/L,Ccat=0.2 g/L453
    Fe基Fe-沸石[73]UV300~4004V=100 mL,pH=3.0,C0=48 μmol/L,Ccat=1 g/L6>9938
    FeO/CS[74]太阳光6V=160 mL,pH=7.0,C0=0.2 mg/L,Ccat=1.0 g/L495.257.20
    CeO2@NiAl-LDHs[69]可见光400~600500V=50 mL,pH=9.0,C0=50 mg/L,Ccat=0.5 g/L590.2
      注:同表1
    下载: 导出CSV
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