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·1318· 精细化工 FINE CHEMICALS 第 39 卷

spectroscopy study of vanadyl phthalocyanine on Au(111): The effect [31] XU X, DAVANCO M, QI X F, et al. Direct transfer patterning on
of oxygen binding and orbital mediated tunneling on the apparent three dimensionally deformed surfaces at micrometer resolutions and
corrugation[J]. Journal of Physical Chemistry B, 2000, 104(25): its application to hemispherical focal plane detector arrays[J].
5993-6000. Organic Electronics, 2008, 9(6): 1122-1127.
[11] TEMPLETON D H, FISCHER M S, ZALKIN A, et al. Structure and [32] YOKOTA T, NAKAMURA T, KATO H, et al. A conformable imager
chemistry of the porphyrins. Crystal and molecular structure of the for biometric authentication and vital sign measurement[J]. Nature
monohydrated dipyridinated magnesium phthalocyanine complex[J]. Electronics, 2020, 3(2): 113-121.
Journal of the American Chemical Society, 1970, 93(11): 2622-2628. [33] NG T N, WONG W S, CHABINYC M L, et al. Flexible image
[12] KONAREV D V, KUZMIN A V, NAKANO Y, et al. Coordination sensor array with bulk heterojunction organic photodiode[J]. Applied
complexes of transition metals (M= Mo, Fe, Rh, and Ru) with tin(Ⅱ) Physics Letters, 2008, 92(21): 191.
phthalocyanine in neutral, monoanionic, and dianionic states[J]. [34] LOCHNER C M, KHAN Y, PIERRE A, et al. All-organic
Inorganic Chemistry, 2016, 55(4): 1390-1402. optoelectronic sensor for pulse oximetry[J]. Nature Communications,
[13] WANG C R, CHEN X, CHEN F, et al. Organic photodetectors based 2014, 5(1): 1-7.
on copper phthalocyanine films prepared by a multiple drop casting [35] CHEN H Y, LIU K W, HU L F, et al. New concept ultraviolet
method[J]. Organic Electronics, 2019, 66: 183-187. photodetectors[J]. Materials Today, 2015, 18(9): 493-502.
[14] CHOI M S, LEE S, KIM H J, et al. Inverted near-infrared organic [36] CHENG Y J, YANG S H, HSU C S. Synthesis of conjugated
photodetector with oriented lead(Ⅱ) phthalocyanine molecules via polymers for organic solar cell applications[J]. Chemical Reviews,
substrate heating[J]. Organic Electronics, 2018, 61: 164-169. 2009, 109(11): 5868-5923.
[15] KIRAN M R, ULLA H, SATYANARAYAN M N, et al. Optoelectronic [37] ZHOU J C, HUANG J. Photodetectors based on organic-inorganic
properties of hybrid diodes based on vanadyl-phthalocyanine and hybrid lead halide perovskites[J]. Advanced Science, 2018, 5(1):
zinc oxide[J]. Superlattices and Microstructures, 2017, 112: 654-664. 1700256.
[16] SHAN H Q, WANG Y L, LI C, et al. Solution-processed near- [38] COWAN S R, BANERJI N, LEONG W L, et al. Charge formation,
infrared phototransistor based on ultrathin nanocrystals of octamethyl recombination, and sweep-out dynamics in organic solar cells[J].
substituted zinc(Ⅱ) phthalocyanine[J]. Organic Electronics, 2018, Advanced Functional Materials, 2012, 22(6): 1116-1128.
58: 197-201 [39] GUO D C (虢德超). Structural design and performance research of
[17] CAMPBELL I H, CRONE B K. A near infrared organic photodiode multiplying organic photodetectors[D]. Guangzhou: South China
with gain at low bias voltage[J]. Applied Physics Letters, 2009, 95(26): University of Technology (华南理工大学), 2020.
336. [40] LIU J S, WANG Y X, WEN H, et al. Organic photodetectors:
[18] LI X L, XIAO Y, WANG S R, et al. Ultra-photosensitive Y-type Materials, structures, and challenges[J]. Solar RRL, 2020, 4(7):
titanylphthalocyanine nanocrystals: Preparation and photoelectric 2000139.
properties[J]. Dyes and Pigments, 2016, 125: 44-53. [41] YANG D (杨丹), ZHANG L (张丽), YANG S Y (杨盛谊), et al.
[19] BOMMER J C, SPIKES J D. Phthalocyanines: Properties and Low-voltage pentacene photodetector based on vertical transistor
applications[J]. Photochemistry and Photobiology, 1991, 53(3): structure[J]. Acta Physica Sinica (物理学报), 2015, (10): 414-419.
419-419. [42] CHAMBERLAIN G A. Organic solar cells: A review[J]. Solar Cells,
[20] MCKEOWN N B. Phthalocyanine materials: Structure, synthesis and 1983, 8(1): 47-83.
function[M]. Cambridge: Cam-bridge University Press, 1998. [43] BAEG K J, BINDA M, NATALI D, et al. Organic light detectors:
[21] FIELDING P E, GUTMAN F. Electrical properties of Photodiodes and phototransistors[J]. Advanced Materials, 2013,
phthalocyanines[J]. The Journal of Chemical Physics, 1957, 26(2): 25(31): 4267-4295.
411-419. [44] DEY P N D, JOSEPH A M, RAKSHIT J K, et al. CuPc/C 60
[22] TORRE G D L, VÁZQUEZ P, AGULLO-LOPEZ F, et al. Role of heterojunction for high responsivity zero bias organic red light
structural factors in the nonlinear optical properties of phthalocyanines photodetector[J]. Applied Physics A, 2020, 126(8): 627.
and related compounds[J]. Chemical Reviews, 2004, 104(9): 3723- [45] WEI G Y, LU Z, CAI Y C, et al. CuPc/C 60 heterojunction
3750. photodetector with near-infrared spectral response[J]. Materials
[23] WEISS D S, ABKOWITZ M. Advances in organic photoconductor Letters, 2017, 201: 137-139.
technology[J]. Chemical Reviews, 2010, 110(1): 479-526. [46] DÖRING S, OTTO T, CEHOVSKI M, et al. Highly sensitive wide
[24] SAKAMOTO K, OHNO-OKUMURA E. Syntheses and functional range organic photodiode based on zinc phthalocyanine: C 60[J].
properties of phthalocyanines[J]. Materials, 2009, 2(3): 1127-1179. Physica Status Solidi A Applications & Materials Science Epss, 2016,
[25] EDWARDS L, GOUTERMAN M. Porphyrins: ⅩⅤ. Vapor absorption 213(9): 2387-2391.
spectra and stability: Phthalocyanines[J]. Journal of Molecular [47] RADISAVLJEVIC B, RADENOVIC A, BRIVIO J, et al. Single-
Spectroscopy, 1970, 33(2): 292-310. layer MoS 2 transistors[J]. Nature Nanotechnology, 2011, 6(3): 147-150.
[26] ISHII K, KOBAYASHI N. Phthalocyanines: Spectroscopic and [48] XU Z H, TANG L, ZHANG S W, et al. 2D MoS 2/CuPc
electrochemical charaterization[M]. Salt Lake City: Academic Press, heterojunction based highly sensitive photodetectors through ultrafast
2003. charge transfer[J]. Materials Today Physics, 2020, 15: 100273.
[27] LOMAX S Q. Phthalocyanine and quinacridone pigments: Their [49] HUANG Y, ZHUGE F W, HOU J X, et al. Van der Waals coupled
history, properties and use[J]. Studies in Conservation, 2005, 50: 19-29. organic molecules with monolayer MoS 2 for fast response
[28] NNAJI N, NWAJI N, MACK J, et al. Corrosion resistance of photodetectors with gate-tunable responsivity[J]. ACS Nano, 2018,
aluminum against acid activation: Impact of benzothiazole-substituted 12(4): 4062-4073.
gallium phthalocyanine[J]. Molecules, 2019, 24(1): 207. [50] HUANG F B, PENG Y Q, LIU G H. Towards ultrahigh sensitivity
[29] PU B Y (浦冰叶). Preparation of high crystallinity phthalocyanine and UV-Vis-NIR broadband response of organolead halide perovskite/
compound by thermally induced crystal formation and its tin-phthalocyanine heterostructured photodetectors[J]. The Journal of
photoconductivity[D]. Tianjin: Tianjin University (天津大学), 2015. Physical Chemistry C, 2019, 123(17): 11073-11080.
[30] REN H, CHEN J D, LI Y Q, et al. Recent progress in organic [51] YANG M, WANG J, ZHAO Y F, et al. Polarimetric three-dimensional
photodetectors and their applications[J]. Advanced Science, 2021, topological insulators/organics thin film heterojunction photodetectors
8(1): 2002418. [J]. ACS Nano, 2019, 13(9): 10810-10817.

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