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·726· 精细化工 FINE CHEMICALS 第 37 卷

3 结论 mesoporous silica modified carbon paste electrode[J]. Journal of
Hazardous Materials, 2016, 318(15): 117-124.
[10] CHU L, HAN L, ZHANG X. Electrochemical simultaneous
（1）利用 MOFs-Fe 为前体，与 Au-NPs 复合后
determination of nitrophenol isomers at nano-gold modified glassy
通过一步热解法制备出 MFPC/Au-NPs 复合材料作 carbon electrode[J]. Journal of Applied Electrochemistry, 2011, 41(6):
为电极传感材料，制备了一种可同时检测 CA 和 HQ 687-694.
[11] ZHANG Min (张敏), CHENG Faliang (程发良), CAI Zhiquan (蔡志
的电化学传感器。泉). Electrochemical study of guanine at nano-gold modified glassy
（2）与 MFPC/GCE、GCE 相比，CA 和 HQ 的 carbon electrode[J]. Journal of Instrumental Analysis (分析测试学
报), 2010, 29(7): 717-720.
氧化峰电流信号在 MFPC/Au-NPs/GCE 上得到显著
[12] XIE W, SU L, DONFACK P, et al. Synthesis of gold nanopeanuts by
增强，表明 MFPC 与 Au-NPs 的协同作用对于 HQ citrate reduction of gold chloride on gold–silver core–shell
和 CA 的氧化具有明显的增敏效应，可以提高其电 nanoparticles[J]. Chemical Communications, 2009, (35): 5263-5265.
[13] LIU W, YANG X, XIE L. Size-controlled gold nanocolloids on
化学响应活性。 polymer microsphere-stabilizer via interaction between functional
（3）该电极材料及传感器与已报道对于 HQ 和 groups and gold nanocolloids[J]. Journal of Colloid and Interface
CA 的传感器相比，制作简单、检测范围宽、灵敏度 Science, 2007, 313(2): 494-502.
[14] CHEN J, SHU Y, LI H, et al. Nickel metal-organic framework 2D
高、检出限低、抗干扰能力强。为同时检测 HQ 和 nanosheets with enhanced peroxidase nanozyme activity for colorimetric
CA 提供了一种简便快速的方法。 detection of H 2O 2[J]. Talanta, 2018, 189: 254-261.
[15] VALIZADEH H, TASHKHOURIAN J, ABBASPOUR A. A carbon
参考文献： paste electrode modified with a metal-organic frame-work of type
MIL-101 (Fe) for voltammetric determination of citric acid[J].
[1] KONG F Y, LI R F, YAO L, et al. Voltammetric simultaneous Microchimica Acta, 2019, 186(7): 455-461.
determination of catechol and hydroquinone using a glassy carbon [16] LI J, XIA J, ZHANG F, et al. An electrochemical sensor based on
electrode modified with a ternary hybrid material composed of reduced copper-based metal-organic frame-works-graphene composites for
graphene oxide, mag-netite nanoparticles and gold nanoparticles[J]. determination of dihydroxybenzene isomers in water[J]. Talanta,
Microchemical Acta, 2019, 186(3): 177-184. 2018, 181(1): 80-86.
[2] SUN A, LI J ,LIU R, et al. High-performance liquid chromatographic [17] WU R, WANG D P, KUMAR V, et al. MOFs-derived copper sulfides
determination of phenolic compounds in natural water coupled with embedded within porous carbon octahedra for electrochemical capacitor
on-line flow injection membrane extraction-preconcentration[J]. Journal applications[J]. Chemical Communications, 2015, 51(15): 3109-3112.
of Separation Science, 2006, 29(7): 995-1000. [18] YAN X, LI X, YAN Z, et al. Porous carbons prepared by direct
[3] LIU Y, WANG Y M, ZHU W Y, et al. Conjugated polymer carbonization of MOFs for supercapacitors[J]. Applied Surface Science,
nanoparticles-based fluorescent biosensor for ultrasen-sitive 2014, 308: 306-310.
detection of hydroquinone[J]. Analytica Chimica Acta, 2018, 1012: [19] FENG X, YIN X, BO X, et al. An ultrasensitive luteolin sensor based
60-65. on MOFs derived CuCo coated nitro-gen-doped porous carbon
[4] ZHAO L J, LV B Q, YUAN H Y, et al. A sensitive chemiluminescence polyhedron[J]. Sensors and Actuators B: Chemical, 2019, 281(15):
method for determination of hydroquinone and catechol[J]. Sensors, 730-738.
2007, 7(4): 578-588. [20] LI F, LI R, FENG Y, et al. Facile synthesis of Au-embedded porous
carbon from metal-organic frameworks and for sensitive detection of
[5] MICHAEL R L S, CHRISTOPHER A R, PATRICK A R, et al. The
acetaminophen in pharmaceutical products[J]. Materials Science and
influence of hydroquinone on tyrosinase kinetics[J]. Bioorganic &
Engineering: C, 2019, 95(1): 78-85.
Medicinal Chemistry, 2012, 20(14): 4364-4370.
[21] SONG G, WANG Z, WANG L, et al. Preparation of MOF(Fe) and its
[6] HAN Kang (韩康), ZHAI Xueliang (翟学良). Determination of catalytic activity for oxygen reduction reaction in an alkaline
hydroquinone, phenol and preservatives in cosmetics by capillary
electrolyte[J]. Chinese Journal of Catalysis, 2014, 35(2): 185-195.
elec-trophoresis[J]. Chinese Journal of Analysis Laboratory (分析试
[22] AHAMMADA J S, SARKER S, RAHMAN M A, et al. Simultaneous
验室), 2011, 30(11): 107-109.
determination of hydroquinone and catechol at an activated glassy
[7] QI H L, ZHANG C X. Simultaneous determination of hydroquinone
carbon electrode[J]. Electroanalysis,2010, 22(6): 694-700.
and catechol at a glassy carbon electrode modified with multiwall [23] REN H, ZHANG Y, LIU L, et al. Synthesis of hollow Mo 2C/carbon
carbon nanotubes[J]. Electroanalysis, 2005, 17(10): 832-838. spheres, and their application to simultaneous electrochemical
[8] CHEN Q, LI X, MIN X, et al. Determination of catechol and detection of hydroquinone, catechol, and resorcinol[J]. Microchimica
hydroquinone with high sensitivity using MOF-graphene composites Acta, 2019, 186(5): 306-314.
modified electrode[J]. Journal of Electroanalytical Chemistry, 2017, [24] NAZARI M, KASHANIAN S, MORADIPOUR P, et al. A novel
789(15): 114-122. fabrication of sensor using ZnO-Al 2O 3 ceramic nanofibers to
[9] TASHKHOURIAN J, DANESHI M, NAMI-ANA F, et al. Simultaneous simultaneously detect catechol and hydroquinone[J]. Journal of
determination of hydroquinone and catechol at gold nanoparticles Electroanalytical Chemistry, 2018, 812(1): 122-131.

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