[1] CHEN K, WANG X F, ZOU C et al. Two-in-one： End-emitting blue LED and self-powered UV photodetector based on single trapezoidal PIN GaN microwire for ambient light UV monitoring and feedback[J]. Small Methods, 7, 2300138(2023).

[2] SOSNA-GLEBSKA A, SIBINSKI M, SZCZECINSKA N et al. UV-Visible silicon detectors with zinc oxide nanoparticles acting as wavelength shifters[J]. Materials Today： Proceedings, 20, 25-29(2022).

[3] XU X, CHEN J X, CAI S et al. A real-time Wearable UV-radiation monitor based on a high-performance p-CuZnS/n-TiO₂ photodetector[J]. Advanced Materials, 30, 1803165(2018).

[4] WEI J Y, SHEN L P, ZHENG Z C et al. The suppression of dark current for achieving high-performance Ga₂O₃ nanorod array ultraviolet photodetector[J]. Ceramics International, 48, 12112-12117(2022).

[5] DALAPATI P, EGAWA T, MIYOSHI M. Current-driven degradation dynamics in GaN/InGaN multi-quantum-wells UV photodetectors fabricated with a high-quality Al₂O₃ passivation film[J]. Vacuum, 213, 112159(2023).

[6] [6] 朱建华，容萍，任帅，等. ZnO 纳米棒/Bi2S3量子点异质结的制备及光电探测性能研究［J］. 光学 精密工程，2022，30（16）：1915-1923. doi: 10.37188/ope.20223016.1915ZHUJ H， RONGP， RENSH， et al. Preparation and photodetection performance of ZnO nanorods/Bi2S3 quantum dots heterojunction［J］. Opt. Precision Eng.， 2022， 30（16）： 1915-1923. （in Chinese）. doi: 10.37188/ope.20223016.1915

[7] HAN Y R, WANG X F, FU S H et al. Ultrahigh detectivity broad spectrum UV photodetector with rapid response speed based on p-β Ga₂O₃/n-GaN heterojunction fabricated by a reversed substitution doping method[J]. Small, 19, 2206664(2023).

[8] WU H S, ZHANG T, SHEN L Y et al. Interfacial engineering of SnS/Ga₂O₃ heterojunction by SnO for a high-performance self-powered solar-blind UV photodetector[J]. Advanced Materials Interfaces, 9, 2200851(2022).

[9] [9] 胡韩飞，徐英添，李莉，等.基于溶胶凝胶法制备的CuCr1-xMgxO2/ZnO纳米棒紫外光电探测器［J］. 光学学报， 2022， 42（14）： 1423001.HUH F， XUY T， LIL， et al. A CuCr1-xMgxO2/ZnO nanorods UV photodetector prepared by Sol-gel method［J］. Acta Optica Sinica， 2022， 42（14）： 1423001. （in Chinese）

[10] NING Y, ZHANG Z, TENG F et al. Novel transparent and self-powered UV photodetector based on crossed ZnO nanofiber array homojunction[J]. Small, 14, 1703754(2018).

[11] SHKIR M. Development of highly sensitive Al， Ga， and In-doped ZnO films by the drop casting method for NH₃ gas sensing[J]. New Journal of Chemistry, 47, 4880-4887(2023).

[12] KUMAR A G, LI X, DU Y et al. UV-Photodetector based on heterostructured ZnO/（Ga，Ag）-co-doped ZnO nanorods by cost-effective two-step process[J]. Applied Surface Science, 509, 144770(2020).

[13] XU M, YUAN Z L, WANG B Y et al. Hydrothermal synthesis of single‑crystalline Ag‑doped ZnO nanoneedles for ultraviolet detection[J]. Journal of Electronic Materials, 51, 7020-7027(2022).

[14] MANOHARAN R, MANJCEEVAN A, VELAUTHAMURTY K et al. Conversion of both photon and mechanical energy into chemical energy using higher concentration of Al doped ZnO[J]. Journal of Alloys and Compounds, 948, 169712(2023).

[15] PHAM A T T, HOANG D V, NGUYEN T H et al. Hydrogen enhancing Ga doping efficiency and electron mobility in high-performance transparent conducting Ga-doped ZnO films[J]. Journal of Alloys and Compounds, 860, 158518(2021).

[16] CHINNASMY M, BALASUBRAMANIAN K. Investigation on laser induced fano resonance of hydrothermally synthesized Ag doped ZnO hierarchical nanoporous structure and its UV photodetector properties[J]. Optical Materials, 133, 112873(2022).

[17] ATIQ S, ANSAR M T, HASSAN A et al. Interlayer effect on photoluminescence enhancement and band gap modulation in Ga-doped ZnO thin films[J]. Superlattices and Microstructures, 144, 106576(2020).

[18] ALI H E, GANESH V, HARRTHA L et al. Kramers-Kronig analysis of the optical linearity and nonlinearity of nanostructured Ga-doped ZnO thin films[J]. Optics and Laser Technology, 135, 106691(2021).

[19] GHAFRY S S AAL, AL-ABRI M Z, FARSI B A et al. Ga-doped ZnO nanorods： The photocatalytic performance of methylene blue under solar irradiation[J]. Optical Materials, 126, 11213(2022).

[20] ZHANG M, ZHOU T, LI H et al. UV-durable superhydrophobic ZnO/SiO₂ nanorod arrays on an aluminum substrate using catalyst-free chemical vapor deposition and their corrosion performance[J]. Applied Surface Science, 623, 157085(2023).

[21] SHINDE S R, SHINDE V P. Liquefied petroleum gas sensing performance of solochemically synthesized ZnO nanorods： Role of precursors and fractal analysis[J]. Sensors and Actuators A： Physical, 345, 113800(2022).

[22] DENG H, FANG B, ZHANG Q et al. Porosity engineering of ZnO nanorods for efficient sensing of n-butanol vapor[J]. Materials Letters, 328, 133169(2022).

[23] MICOVA J, REMES Z, ARTEMENKO A et al. Plasma treatment of Ga-doped ZnO nanorods[J]. Physica Status Solidi A, 219, 2100663(2022).

[24] PHAN D T, CHUNG G S. Effects of defects in Ga-doped ZnO nanorods formed by a hydrothermal method on CO sensing properties[J]. Sensors and Actuators B： Chemical, 187, 191-197(2013).

[25] SINGH P, SIMANJUNTAK F M, KUMAR A et al. Resistive switching behavior of Ga doped ZnO-nanorods film conductive bridge random access memory[J]. Thin Solid Films, 660, 828-833(2018).

[26] KUMAR K D A, MELE P, MURAHARI P et al. Enhancement of performance of Ga incorporated ZnO UV photodetectors prepared by simplified two step chemical solution process[J]. Sensors and Actuators：, 333, 113217(2022).

[27] YANG M L, WENG X L, IQBAL M A et al. Broadband photoresponse in plasmon-enhanced Ga-doped ZnO[J]. Materials Advances, 4, 2226-2233(2023).

[28] HSIAO C H, HUANG C S, YOUNG S J et al. Field-emission and photoelectrical characteristics of Ga-ZnO nanorods photodetector[J]. IEEE Transactions on Electron Devices, 60, 1905-1910(2013).

[29] YOUNG S J, CHIOU C L. Synthesis and optoelectronic properties of Ga-doped ZnO nanorods by hydrothermal method[J]. Microsystem Technologies, 24, 103-107(2018).

[30] YOUNG S J, CHIOU C L, LIU Y H et al. Synthesis of Ga-doped ZnO nanorods by hydrothermal method and their application to ultraviolet photodetector[J]. Inventions, 1, 3(2016).

[31] YOUNG S J, LIU Y H, SHIBLEE M D N I et al. Flexible ultraviolet photodetectors based on one-dimensional gallium-doped zinc oxide nanostructures[J]. ACS Applied Electronic Materials, 2, 3522-3529(2020).

[32] CHU Y L, YOUNG S J, CHU T T et al. Improvement of the UV-sensing performance of ga-doped ZnO nanostructures via a wet chemical solution at room temperature[J]. ECS Journal of Solid State Science and Technology, 10, 127001(2021).

[33] WU H, YUAN Z L, WANG B Y et al. Synthesis of single-crystalline ZnO nanoflowers for a superhigh-sensitivity ultraviolet photodetector application[J]. Optical Materials, 122, 111683(2021).

[34] LUO P, WANG F, QU J et al. Self-driven WSe₂/Bi₂O₂Se van der waals heterostructure photodetectors with high light On/Off ratio and fast response[J]. Advanced Functional Materials, 31, 2008351(2021).

[35] ZHENG H, JIANG Y, YANG S et al. ZnO nanorods array as light absorption antenna for high-gain UV photodetectors[J]. Journal of Alloys and Compounds, 812, 152158(2020).

[36] [36] 袁兆林，胡宇杰，吕季辉，等.ZnO纳米线阵列/PVK异质结紫外光探测器特性［J］. 光学学报，2022，42（22）： 2204001. doi: 10.3788/AOS202242.2204001YUANZH L， HUY J， LÜJ H， et al. Characteristics of ZnO nanowire arrays/PVK heterojunction ultraviolet photodetector［J］. Acta Optica Sinica， 2022， 42（22）： 2204001. （in Chinese）. doi: 10.3788/AOS202242.2204001

[37] XU N C, YUAN Z L, NIE F J et al. Hydrothermal growth and ultraviolet sensing performance of well-aligned Ga-doped ZnO nanowire arrays[J]. Optical Materials, 133, 112995(2022).

[38] KUMAR C, KUSHWAHA B K, KUMAR A et al. Fibrous Al-Doped ZnO thin film ultraviolet photodetectors with improved responsivity and speed[J]. IEEE Photonics Technology Letters, 32, 337-340(2020).

[39] JENISH S L, VALANARASU S, PRAKASH B et al. Improved optical and electrical properties of Fe doped ZnO nanostructures facilely deposited by low-cost SILAR method for photosensor applications[J]. Surfaces and Interfaces, 31, 102071(2022).