掺杂石墨烯的ZnO复合材料研究进展

摘要/Abstract

摘要： ZnO是一种低成本且应用广泛的材料,石墨烯具有较大的比表面积以及优良的吸附、光电等特性,易于与ZnO结合,可提高ZnO的性能。掺杂石墨烯的ZnO基材料在气体检测、抗菌表面涂层、发光二极管、透明导电电极和光催化等方面都有着应用性。本文概述了近几年来石墨烯掺杂ZnO材料作为导电薄膜、传感器、光催化剂等在光电子、生物医疗、环保等不同领域内的研究与发展,提出了目前该复合材料在制备工艺复杂与可控性差,实际应用与理论有较大差距等问题,并对未来的研究趋势进行了预测和展望。

关键词: ZnO, 石墨烯, 光催化, 气敏传感器, 透明导电薄膜, 纳米材料

Abstract: Nanomaterials have excellent anomalous, abnormal electrical, optical, mechanical and catalytic properties, opening up new research and application fields for the research of new materials. Zinc oxide has the advantages of low cost, non-toxic and harmless, large band gap width and high electronic excitation energy, and has been widely used in the development of functional devices. However, ZnO has some defects, such as oxygen vacancies (V_o) and zinc deficiency (Zn_i), rapid recombination rate of photoelectron-hole pairs and low adsorption properties. Doping can change the structure of the material and improve its performance. Graphene is a two-dimensional planar structure material with a thickness of only one atomic layer. Its microstructure is a sp² hexagonal atomic network with allotropes of G, GO and rGO. It has a special structure and good properties. Its excellent stability and large specific surface area make it easy to mix with other materials. These properties all help to improve the performance of ZnO nanoparticles. Recent applications of graphene/zinc oxide composite materials in the fields of photocatalysis, sensing, transparent conductive films, optical detection, and electrodes were introduced. The addition of graphene can control defects. The best defects of ZnO/rGO not only increase the surface and carrier concentration of ZnO/rGO but also provide auxiliary carrier paths, supplemented by rGO flakes for electron-hole separation and extended carrier recombination. These characteristics are very suitable for light detection and photocatalysis applications. Due to the high surface area of graphene, a p-n junction is formed between rGO and ZnO nanoparticles. ZnO/rGO composite material has excellent responsiveness and selectivity to gases, and the combination of rGO nanocrystals and ZnO plays a vital role in enhancing detection performance. Adding metal ions and graphene to ZnO can effectively reduce the square resistance of the film. Vacuum annealing and annealing in Ar+H₂ can make electrical properties more excellent because annealing reduces internal defects and disorder. The carrier mobility of graphene at room temperature is about 15 000 cm²/(V·s). Unlike many materials, the electron mobility of graphene is less affected by temperature changes. The optical and electrical parameters of the ZnO/graphene composite film increase the possibility of becoming a transparent conductive electrode. In addition, it can also be used as a photodetector, diode, etc. The composite of ZnO and graphene has a good influence on the development of many fields in the future, and it is still a hot spot and trend of research.

Key words: ZnO, graphene, photocatalytic, gas sensor, transparent conductive film, nanomaterial

中图分类号:

TB34

盛浩, 刘琳, 徐键, 卢焕明. 掺杂石墨烯的ZnO复合材料研究进展[J]. 硅酸盐通报, 2021, 40(3): 999-1006.

SHENG Hao, LIU Lin, XU Jian, LU Huanming. Research and Development on Graphene Doped ZnO Composites[J]. BULLETIN OF THE CHINESE CERAMIC SOCIETY, 2021, 40(3): 999-1006.

参考文献

[1] 林晓君,司徒丹娜,胡宁洋,等.掺杂ZnO微纳米材料的制备及应用研究[J].广州化工,2020,48(1):20-22.
LIN X J, SITU D N, HU N Y, et al. Fabrication and application of doped ZnO micro- and nano-materials[J]. Guangzhou Chemical Industry, 2020, 48(1): 20-22 (in Chinese).
[2] PALIWAL A, SHARMA A, TOMAR M, et al. Carbon monoxide (CO) optical gas sensor based on ZnO thin films[J]. Sensors and Actuators B: Chemical, 2017, 250: 679-685.
[3] PONHAN W, PHADUNGDHITIDHADA S, CHOOPUN S. Fabrication of ethanol sensors based on ZnO thin film field-effect transistor prepared by thermal evaporation deposition[J]. Materials Today: Proceedings, 2017, 4(5): 6342-6348.
[4] EDINGER S, BANSAL N, BAUCH M, et al. Highly transparent and conductive indium-doped zinc oxide films deposited at low substrate temperature by spray pyrolysis from water-based solutions[J]. Journal of Materials Science, 2017, 52(14): 8591-8602.
[5] CHOO T F, SAIDIN N U, KOK K Y. A novel self-heating zinc oxide/indium tin oxide based hydrogen gas sensor: dual sensing mode of hydrogen gas detection[J]. Chemical Physics Letters, 2018, 713: 180-184.
[6] 吴兴东,吴兆丰.ZnO基透明导电薄膜的研究应用进展[J].科技视界,2012(3):54-57.
WU X D, WU Z F. Research and application progress of ZnO-based transparent conductive film[J]. Science & Technology Vision, 2012(3): 54-57 (in Chinese).
[7] HAGHSHENAS S S P, NEMATI A, SIMCHI R, et al. Photocatalytic and photoluminescence properties of ZnO/graphene quasi core-shell nanoparticles[J]. Ceramics International, 2019, 45(7): 8945-8961.
[8] NAIR R R, BLAKE P, GRIGORENKO A N, et al. Fine structure constant defines visual transparency of graphene[J]. Science, 2008, 320(5881): 1308.
[9] WANG J G, MA F C, SUN M T. Graphene, hexagonal boron nitride, and their heterostructures: properties and applications[J]. RSC Advances, 2017, 7(27): 16801-16822.
[10] WAN Q, WANG H Y, LI S Y, et al. Efficient liquid-phase exfoliation of few-layer graphene in aqueous 1, 1, 3, 3-tetramethylurea solution[J]. Journal of Colloid and Interface Science, 2018, 526: 167-173.
[11] HINTZE C, MORITA K, RIEDEL R, et al. Facile sol-gel synthesis of reduced graphene oxide/silica nanocomposites[J]. Journal of the European Ceramic Society, 2016, 36(12): 2923-2930.
[12] LI X S, MAGNUSON C W, VENUGOPAL A, et al. Large-area graphene single crystals grown by low-pressure chemical vapor deposition of methane on copper[J]. Journal of the American Chemical Society, 2011, 133(9): 2816-2819.
[13] JASTRZĘBSKA A M, KARCZ J, LETMANOWSKI R, et al. Synthesis of RGO/TiO₂ nanocomposite flakes and characterization of their unique electrostatic properties using zeta potential measurements[J]. Journal of Alloys and Compounds, 2016, 679: 470-484.
[14] ZHANG X J, DONG P Y, ZHANG B G, et al. Preparation and characterization of reduced graphene oxide/copper composites incorporated with nano-SiO₂ particles[J]. Journal of Alloys and Compounds, 2016, 671: 465-472.
[15] CHUA C K, PUMERA M. Covalent chemistry on graphene[J]. Chemical Society Reviews, 2013, 42(8): 3222-3233.
[16] CHENG C, LI D. Solvated graphenes: an emerging class of functional soft materials[J]. Advanced Materials, 2013, 25(1): 13-30.
[17] 张则瑞,吴建东,王立国,等.氧化石墨烯(GO)在水泥基复合材料中的应用研究进展[J].硅酸盐通报,2017,36(9):3008-3012+3019.
ZHANG Z R, WU J D, WANG L G, et al. Research progress on application of graphene oxide in cement matrix composites[J]. Bulletin of the Chinese Ceramic Society, 2017, 36(9): 3008-3012+3019 (in Chinese).
[18] WEI S Y, YU Q X, FAN Z G, et al. Fabricating high thermal conductivity rGO/polyimide nanocomposite films via a freeze-drying approach[J]. RSC Advances, 2018, 8(39): 22169-22176.
[19] RODWIHOK C, WONGRATANAPHISAN D, THINGO Y L, et al. Effect of GO additive in ZnO/rGO nanocomposites with enhanced photosensitivity and photocatalytic activity[J]. Nanomaterials, 2019, 9(10): 1441.
[20] 韩军凯,冯奕钰,封伟.掺杂石墨烯制备方法新进展[J].天津大学学报(自然科学与工程技术版),2020,53(5):467-474.
HAN J K, FENG Y Y, FENG W. Recent research progress in doped-graphene preparation[J]. Journal of Tianjin University (Science and Technology), 2020, 53(5): 467-474 (in Chinese).
[21] 匡达,胡文彬.石墨烯复合材料的研究进展[J].无机材料学报,2013,28(3):235-246.
KUANG D, HU W B. Research progress of graphene composites[J]. Journal of Inorganic Materials, 2013, 28(3): 235-246 (in Chinese).
[22] VAN TUAN P, PHUONG T T, TAN V T, et al. In-situ hydrothermal fabrication and photocatalytic behavior of ZnO/reduced graphene oxide nanocomposites with varying graphene oxide concentrations[J]. Materials Science in Semiconductor Processing, 2020, 115: 105114.
[23] 许兰兰,王松,刘玉霞,等.微波法合成金属-有机骨架材料研究应用进展[J].化工新型材料,2019,47(4):1-5.
XU L L, WANG S, LIU Y X, et al. Advance on research and application of MOF prepared by MW method[J]. New Chemical Materials, 2019, 47(4): 1-5 (in Chinese).
[24] DOU P T, TAN F T, WANG W, et al. One-step microwave-assisted synthesis of Ag/ZnO/graphene nanocomposites with enhanced photocatalytic activity[J]. Journal of Photochemistry and Photobiology A: Chemistry, 2015, 302: 17-22.
[25] AZIZ T N T A, ROSLI A B, YUSOFF M M, et al. Transparent hybrid ZnO-graphene film for high stability switching behavior of memristor device[J]. Materials Science in Semiconductor Processing, 2019, 89: 68-76.
[26] GÜLER Ö, GÜLER S H, BAŞGÖZ Ö, et al. Synthesis and characterization of ZnO-reinforced with graphene nanolayer nanocomposites: electrical conductivity and optical band gap analysis[J]. Materials Research Express, 2019, 6(9): 095602.
[27] SHAO S F, CHEN X, CHEN Y Y, et al. ZnO nanosheets modified with graphene quantum dots and SnO₂ quantum nanoparticles for room-temperature H₂S sensing[J]. ACS Applied Nano Materials, 2020, 3(6): 5220-5230.
[28] DRMOSH Q A, YAMANI Z H, HENDI A H, et al. A novel approach to fabricating a ternary rGO/ZnO/Pt system for high-performance hydrogen sensor at low operating temperatures[J]. Applied Surface Science, 2019, 464: 616-626.
[29] 李琦,罗志刚,陈大勇,等.氧化锌/石墨烯复合材料的制备及其光催化性能[J].上海大学学报(自然科学版),2020,26(3):425-432.
LI Q, LUO Z G, CHEN D Y, et al. Preparation and photocatalytic properties of ZnO/graphene composite[J]. Journal of Shanghai University (Natural Science Edition), 2020, 26(3): 425-432 (in Chinese).
[30] SU B T, DONG Y Y, JIN Z J, et al. Enhanced photocatalytic performance of ZnO/rGO composite materials prepared via an improved two-steps method[J]. Ceramics International, 2016, 42(6): 7632-7638.
[31] WANG K, XU J M, WANG X T. The effects of ZnO morphology on photocatalytic efficiency of ZnO/RGO nanocomposites[J]. Applied Surface Science, 2016, 360: 270-275.
[32] FENG Y, FENG N N, WEI Y Z, et al. An in situ gelatin-assisted hydrothermal synthesis of ZnO-reduced graphene oxide composites with enhanced photocatalytic performance under ultraviolet and visible light[J]. RSC Advances, 2014, 4(16): 7933.
[33] 唐伟.基于碳纳米材料的柔性气体传感器的研究进展[J].硅酸盐通报,2019,38(2):398-409.
TANG W. Research progress of flexible gas sensors based on carbon nanomaterials[J]. Bulletin of the Chinese Ceramic Society, 2019, 38(2): 398-409 (in Chinese).
[34] BALASUBRAMANI V, SURESHKUMAR S, RAO T S, et al. Impedance spectroscopy-based reduced graphene oxide-incorporated ZnO composite sensor for H₂S investigations[J]. ACS Omega, 2019, 4(6): 9976-9982.
[35] ALFANO B, MIGLIETTA M L, POLICHETTI T, et al. Improvement of NO₂ detection: graphene decorated with ZnO nanoparticles[J]. IEEE Sensors Journal, 2019, 19(19): 8751-8757.
[36] CAO P J, CAI Y Z, PAWAR D, et al. Down to ppb level NO₂ detection by ZnO/rGO heterojunction based chemiresistive sensors[J]. Chemical Engineering Journal, 2020, 401: 125491.
[37] UGALE A D, UMARJI G G, JUNG S H, et al. ZnO decorated flexible and strong graphene fibers for sensing NO₂ and H₂S at room temperature[J]. Sensors and Actuators B: Chemical, 2020, 308: 127690.
[38] GALSTYAN V, COMINI E, KHOLMANOV I, et al. Reduced graphene oxide/ZnO nanocomposite for application in chemical gas sensors[J]. RSC Advances, 2016, 6(41): 34225-34232.
[39] DHINGRA V, KUMAR S, KUMAR R, et al. Room temperature SO₂ and H₂ gas sensing using hydrothermally grown GO-ZnO nanorod composite films[J]. Materials Research Express, 2020, 7(6): 065012.
[40] CHOU C T, WANG F H, CHEN W C. Effects of concentration of reduced graphene oxide on properties of sol-gel prepared Al-doped zinc oxide thin films[J]. Thin Solid Films, 2016, 605: 143-148.
[41] YU X Y, XU J, LU H M, et al. Sol-gel derived Al-doped zinc oxide-reduced graphene oxide nanocomposite thin films[J]. Journal of Alloys and Compounds, 2017, 699: 79-86.
[42] KINDALKAR V S, SANDEEP K M, KUMARA K, et al. Sol-gel synthesized spin coated GO∶ZnO composite thin films: optical, structural and electrical studies[J]. Materials Research Express, 2019, 6(9): 096435.
[43] 何延如,田小让,赵冠超,等.石墨烯薄膜的制备方法及应用研究进展[J].材料导报,2020,34(5):5048-5060+5077.
HE Y R, TIAN X R, ZHAO G C, et al. Research progress in preparation and application of graphene films[J]. Materials Reports, 2020, 34(5): 5048-5060+5077 (in Chinese).
[44] TSAI Y S, CHEN Y Y, XU C Y, et al. Influence of reduced graphene oxide on material, antibacterial, and piezoelectric behaviors of ZnO nanorods on foldable indium tin oxide substrates[J]. Journal of Materials Science: Materials in Electronics, 2019, 30(14): 13167-13173.
[45] TAN Q K, KONG Z, GUAN X G, et al. Hierarchical zinc oxide/reduced graphene oxide composite: preparation route, mechanism study and lithium ion storage[J]. Journal of Colloid and Interface Science, 2019, 548: 233-243.
[46] MOUSAVI S S, KAZEMPOUR A, EFAFI B, et al. Effects of graphene quantum dots interlayer on performance of ZnO-based photodetectors[J]. Applied Surface Science, 2019, 493: 1187-1194.
[47] KOÇ M M, ASLAN N, ERKOVAN M, et al. Electrical characterization of solar sensitive zinc oxide doped-amorphous carbon photodiode[J]. Optik, 2019, 178: 316-326.
[48] SREEJA V G, ANILA E I. Studies on the effect of reduced graphene oxide on nonlinear absorption and optical limiting properties of potassium doped zinc oxide thin film by Z-scan technique[J]. Thin Solid Films, 2019, 685: 161-167.