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·1774· 精细化工 FINE CHEMICALS 第 37 卷

for oncogenic BRAF signalling and tumorigenesis[J]. Nature, 2014, [34] KAUR N, KAUR M, CHOPRA S, et al. Fe (Ⅲ) conjugated
509: 492-496. fluorescent organic nanoparticles for ratiometric detection of tyramine
[25] GAGGELLI E, KOZLOWSKI H, VALENSIN D, et al. Copper in aqueous medium: A novel method to determine food quality[J].
homeostasis and neurodegenerative disorders (Alzheimer's, prion, Food Chemistry, 2018, 245: 1257-1261.
and Parkinson's diseases and amyotrophic lateral sclerosis)[J]. [35] WANG H, WANG J L, YANG S X, et al. Highly selective and
Chemical Reviews, 2006, 106: 1995-2044. rapidly responsive fluorescent probe for hydrogen sulfide detection
[26] National Standardization Administration of China. General analysis in wine[J]. Food Chemistry, 2018, 257: 150-154.
method for wine and fruit wine: GB15038—2006[S]. Beijing: China [36] REN A, ZHU D J, XIE W, et al. A novel reaction-based fluorescent
2+
Standard Press(中国标准出版社), 2006: 17. probe for sensitive and selective detection of Cu [J]. Inorganica
[27] SEEGER T S, ROSA F C, BIZZI C A, et al. Feasibility of dispersive Chimica Acta, 2018, 476: 136-141.
liquid-liquid microextraction for extraction and preconcentration of [37] GU B, HUANG L Y, XU Z F, et al. A reaction-based, colorimetric
2+
Cu and Fe in red and white wine and determination by flame atomic and near-infrared fluorescent probe for Cu and its applications[J].
absorption spectrometry[J]. Spectrochimica Acta, Part B: Atomic Sensors & Actuators, B: Chemical, 2018, 273: 118-125.
Spectroscopy, 2015, 105: 136-140. [38] NGUYEN K H, HAO Y Q, ZENG K, et al. A reaction-based
2+
[28] SHIRAISHI Y, TANAKA K, HIRAI T. Colorimetric sensing of Cu long-wavelength fluorescent probe for Cu detection and imaging in
(Ⅱ) in aqueous media with a spiropyran derivative via a oxidative living cells[J]. Journal of Photochemistry & Photobiology, A:
dehydrogenation mechanism[J]. ACS Applied Materials & Interfaces, Chemistry, 2018, 358: 201-206.
2013, 5: 3456-3463. [39] LI N, XIANG Y, TONG A J. Highly sensitive and selective “turn-on”
2+
2+
[29] PANEQUE P, ÁLVAREZ-SOTOMAYOR M T, CLAVIJO A, et al. fluorescent chemodosimeter for Cu in water via Cu -promoted
Metal content in southern Spain wines and their classification hydrolysis of lactone moiety in coumarin[J]. Chemical Communications,
according to origin and ageing[J]. Microchemical Journal, 2010, 94: 2010, 46: 3363-3365.
175-179. [40] LI H, ZHANG P, SMAGA L P, et al. Photoacoustic probes for
[30] ALMEIDA C M R, VASCONCELOS M T S. Multielement ratiometric imaging of copper (Ⅱ)[J]. Journal of the American
composition of wines and their precursors including provenance soil Chemical Society, 2015, 137: 15628-15631.
and their potentialities as fingerprints of wine origin[J]. Journal [41] SUN J, WANG B, ZHAO X, et al. Fluorescent and colorimetric
2+
Agricultural Food Chemistry, 2003, 51: 4788-4798. dual-readout assay for inorganic pyrophosphatase with Cu -triggered
[31] AJTONY Z, SZOBOSZLAI N, SUSKÓ E K, et al. Direct sample oxidation of o-phenylenediamine[J]. Analytical Chemistry, 2016, 88:
introduction of wines in graphite furnace atomic absorption spectrometry 1355-1361.
for the simultaneous determination of arsenic, cadmium, copper and [42] HU X X, ZHENG X L, FAN X X, et al. Semicarbazide-based
lead content[J]. Talanta, 2008, 76: 627-634. naphthalimide as a highly selective and sensitive colorimetric and
2+
[32] MORENO I M, GONZÁLEZ-WELLER D, GUTIERREZ V, et al. “turn-on” fluorescent chemodosimeter for Cu [J]. Sensors &
Determination of Al, Ba, Ca, Cu, Fe, K, Mg, Mn, Na, Sr and Zn in Actuators, B: Chemical, 2016, 227: 191-197.
2+
red wine samples by inductively coupled plasma optical emission [43] RYU H, CHOI M G, CHO E J, et al. Cu -selective fluorescent probe
spectroscopy: Evaluation of preliminary sample treatments[J]. based on the hydrolysis of semicarbazide derivative of 2-(2-aminophenyl)
Microchemical Journal, 2008, 88: 56-61. benzothiazole[J]. Dyes and Pigments, 2018, 149: 620-625.
[33] WU Z Z, XU E B, CHUGHTAI M F, et al. Highly sensitive [44] DESHPANDE S S, KHOPKAR S S, SHANKARLING G S. A
fluorescence sensing of zearalenone using a novel aptasensor based on thiazoloquinoxaline based “turn-on” chemodosimeter for detection of
upconverting nanoparticles[J]. Food Chemistry, 2017, 230: 673-680. copper ions[J]. Dyes and Pigments, 2017, 147: 393-399.

（上接第 1743 页） mesoporous copper ferrite as a heterogeneous Fenton catalyst for the
degradation of imidacloprid[J]. Applied Catalysis B: Environmental,
[42] BAO T, JIN J, DAMTIE M M, et al. Green synthesis and application 2014, 147: 534-545.
of nanoscale zero-valent iron/rectorite composite material for [49] HASSAN M, ASHRAF G A, ZHANG B, et al. Energy-efficient
p-chlorophenol degradation via heterogeneous Fenton reaction[J]. degradation of antibiotics in microbial electro-Fenton system
Journal of Saudi Chemical Society, 2019, 23(7): 864-878. catalysed by M-type strontium hexaferrite nanoparticles[J]. Chemical
[43] SHARMA A, DUTTA R K, ROYCHOWDHURY A, et al. Studies on Engineering Journal, 2020, 380: 122483.
structural defects in bare, PVP capped and TPPO capped copper [50] MALAKOOTIAN M, NASIRI A, GHARAGHANI M A.
oxide nanoparticles by positron annihilation lifetime spectroscopy Photocatalytic degradation of ciprofloxacin antibiotic by TiO 2
and their impact on photocatalytic degradation of Rhodamine B[J]. nanoparticles immobilized on a glass plate[J]. Chemical Engineering
RSC Advances, 2016, 6(78): 74812-74821.
Communications, 2020, 207(1): 56-72.
[44] SANGAMI S, MANU B. Synthesis of green iron nanoparticles using [51] ZHU K R, XU H, CHEN C L, et al. Encapsulation of Fe -dominated
0
laterite and their application as a Fenton-like catalyst for the Fe 3O 4/Fe /Fe 3C nanoparticles into carbonized polydopamine
0
degradation of Herbicide Ametryn in water[J]. Environmental
Technology & Innovation, 2017, 8: 150-163. nanospheres for catalytic degradation of tetracycline via persulfate
[45] KHUNTIA B K, ANWAR M F, ALAM T, et al. Synthesis and activation[J]. Chemical Engineering Journal, 2019, 372: 304-311.
characterization of zero-valent iron nanoparticles, and the study of [52] ZHU G P, YU X D, XIE F, et al. Ultraviolet light assisted
their effect against the degradation of DDT in soil and assessment of heterogeneous Fenton degradation of tetracycline based on
their toxicity against collembola and ostracods[J]. ACS Omega, polyhedral Fe 3O 4 nanoparticles with exposed high-energy {110}
2019, 4(20): 18502-18509. facets[J]. Applied Surface Science, 2019, 485: 496-505.
[46] XIE Z R, WANG C X, YIN L W. Nickel-assisted iron oxide catalysts [53] BAI Z Y, YANG Q, WANG J L. Degradation of sulfamethazine
for the enhanced degradation of refractory DDT in heterogeneous antibiotics in Fenton-like system using Fe 3O 4 magnetic nanoparticles
Fenton-like system[J]. Journal of Catalysis, 2017, 353: 11-18. as catalyst[J]. Environmental Progress & Sustainable Energy, 2017,
[47] ZANGIABADI M, SALJOOQI A, SHAMSPUR T, et al. Evaluation 36(6): 1743-1753.
of GO nanosheets decorated by CuFe 2O 4 and CdS nanoparticles as [54] TANG J T, WANG J L. MOF-derived three-dimensional flower-like
photocatalyst for the degradation of dinoseb and imidacloprid FeCu@C composite as an efficient Fenton-like catalyst for
pesticides[J]. Ceramics International, 2020, 46(5): 6124-6128. sulfamethazine degradation[J]. Chemical Engineering Journal, 2019,
[48] WANG Y B, ZHAO H Y, LI M F, et al. Magnetic ordered 375: 122007.

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