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Xiaofei Yang, Jieling Qin, Yang Li, et al. Graphene-Spindle Shaped Tio2 Mesocrystal Composites: Facile Synthesis and Enhanced Visible Light Photocatalytic Performance. Journal of Hazardous Materials 2013; 261: 342–350.YangXiaofeiQinJielingLiYangGraphene-Spindle Shaped Tio2 Mesocrystal Composites: Facile Synthesis and Enhanced Visible Light Photocatalytic PerformanceJournal of Hazardous Materials201326134235010.1016/j.jhazmat.2013.07.04423959254Search in Google Scholar
Jing Li, Shilin Zhou, GuiBing Hong, et al. Hydrothermal Preparation of P25–Graphene Composite with Enhanced Adsorption and Photocatalytic Degradation of Dyes. Chemical Engineering Journal 2013; 219: 486–491.LiJingZhouShilinHongGuiBingHydrothermal Preparation of P25–Graphene Composite with Enhanced Adsorption and Photocatalytic Degradation of DyesChemical Engineering Journal201321948649110.1016/j.cej.2013.01.031Search in Google Scholar
Wang F, Zhang K. Reduced Graphene Oxide–Tio2 Nanocomposite with High Photocatalystic Activity for the Degradation Of Rhodamine B. Journal of Molecular Catalysis A: Chemical 2011; 345: 101–107.WangFZhangKReduced Graphene Oxide–Tio2 Nanocomposite with High Photocatalystic Activity for the Degradation Of Rhodamine BJournal of Molecular Catalysis A: Chemical201134510110710.1016/j.molcata.2011.05.026Search in Google Scholar
Mrinmay D, Joydeep D, Sayantan S, et al. Equivalent Circuit Analysis of Al/Rgo-Tio2 Metal-Semiconductor Interface via Impedance Spectroscopy: Graphene Induced Improvement in Carrier Mobility and Lifetime. Materials Science in Semiconductor Processing 2018; 82: 104–111.MrinmayDJoydeepDSayantanSEquivalent Circuit Analysis of Al/Rgo-Tio2 Metal-Semiconductor Interface via Impedance Spectroscopy: Graphene Induced Improvement in Carrier Mobility and LifetimeMaterials Science in Semiconductor Processing20188210411110.1016/j.mssp.2018.03.039Search in Google Scholar
Pei Fuyun, Xu Shengang, Liu Yingliang, et al. Photocatalytic Hydrogen Evolution from Water by Dye-Sensitized Titania/Graphene Nanocomposite. CIESC Journal 2013; 64: 3062–3069.FuyunPeiShengangXuYingliangLiuPhotocatalytic Hydrogen Evolution from Water by Dye-Sensitized Titania/Graphene NanocompositeCIESC Journal20136430623069Search in Google Scholar
Haihua Yang, Stephen VK, Yu Wang, et al. Shuttling Photoelectrochemical Electron Transport in Tricomponent Cds/Rgo/Tio2 Nanocomposites. The Journal of Physical Chemistry C 2013; 117: 20406–20414.YangHaihuaStephenVKYuWangShuttling Photoelectrochemical Electron Transport in Tricomponent Cds/Rgo/Tio2 NanocompositesThe Journal of Physical Chemistry C2013117204062041410.1021/jp405227tSearch in Google Scholar
Alenizi MA, Alseroury FA, Kumar R, et al. Removal of Trichlorophenol from Wastewater Using Nis/RGO/Tio2 Composite as an Efficient Photocatalyst under Sunlight. Composites 2020; 24: 26.AleniziMAAlserouryFAKumarRRemoval of Trichlorophenol from Wastewater Using Nis/RGO/Tio2 Composite as an Efficient Photocatalyst under SunlightComposites2020242610.5004/dwt.2020.24795Search in Google Scholar
Kalyani R, Gurunathan K. Pth-Rgo-Tio2 Nanocomposite for Photocatalytic Hydrogen Production and Dye Degradation. Journal of Photochemistry and Photobiology A: Chemistry 2016; 329: 105–112.KalyaniRGurunathanKPth-Rgo-Tio2 Nanocomposite for Photocatalytic Hydrogen Production and Dye DegradationJournal of Photochemistry and Photobiology A: Chemistry201632910511210.1016/j.jphotochem.2016.05.026Search in Google Scholar
Huogen Yu, Pian Xiao, Jing Tian, et al. Phenylamine-Functionalized Rgo/Tio2 Photocatalysts: Spatially Separated Adsorption Sites and Tunable Photocatalytic Selectivity. ACS Applied Materials & Interfaces 2016; 8: 29470–29477.YuHuogenXiaoPianTianJingPhenylamine-Functionalized Rgo/Tio2 Photocatalysts: Spatially Separated Adsorption Sites and Tunable Photocatalytic SelectivityACS Applied Materials & Interfaces20168294702947710.1021/acsami.6b0990327734674Search in Google Scholar
Ren Jian, Li Guangzhao, Han Rui, et al. In-Situ Preparation of Reduced Graphene Oxide/Titanium Dioxide Composites by Sol-Gel Method and their Photocatalytic Properties. Journal of Functional Materials 2019; 50:7185–7190+7198.JianRenGuangzhaoLiRuiHanIn-Situ Preparation of Reduced Graphene Oxide/Titanium Dioxide Composites by Sol-Gel Method and their Photocatalytic PropertiesJournal of Functional Materials20195071857190+7198Search in Google Scholar
Yibing Li, Haimin Zhang, Porun Liu, et al. Cross-linked g-C3N4/rGO Nanocomposites with Tunable Band Structure and Enhanced Visible Light Photocatalytic Activity. Small 2013; 9: 3336–3344.LiYibingZhangHaiminLiuPorunCross-linked g-C3N4/rGO Nanocomposites with Tunable Band Structure and Enhanced Visible Light Photocatalytic ActivitySmall201393336334410.1002/smll.20120313523630157Search in Google Scholar
Hummers Jr W S, Offeman R E. Preparation of Graphitic Oxide. Journal of the American Chemical Society 1958; 80: 1339–1339.HummersW SJrOffemanR EPreparation of Graphitic OxideJournal of the American Chemical Society1958801339133910.1021/ja01539a017Search in Google Scholar
Lv Sailong, Huo Ruiting, Jia Guoqiang. Preparation and Properties of Photo-Catalytic Self-Cleaning Coated Fabrics. Journal of Textile Research 2018; 39: 87–91.SailongLvRuitingHuoGuoqiangJiaPreparation and Properties of Photo-Catalytic Self-Cleaning Coated FabricsJournal of Textile Research2018398791Search in Google Scholar
Tian Shengnan, Zhao Jian, Chen Lingling, et al. Preparation And Properties Of Self-Cleaning Fabrics Based on Ag / TiO2 Photocatalysis. Journal of Textile Research 2018; 39: 89–94.ShengnanTianJianZhaoLinglingChenPreparation And Properties Of Self-Cleaning Fabrics Based on Ag / TiO2 PhotocatalysisJournal of Textile Research2018398994Search in Google Scholar
Jian Yu, Zengyuan Pang, Chenghui Zheng, et al. Cotton Fabric Finished bBy PANI/TiO2 with Multifunctions of Conductivity, Anti-Ultraviolet and Photocatalysis Activity. Applied Surface Science 2019; 470: 84–90.YuJianPangZengyuanZhengChenghuiCotton Fabric Finished bBy PANI/TiO2 with Multifunctions of Conductivity, Anti-Ultraviolet and Photocatalysis ActivityApplied Surface Science2019470849010.1016/j.apsusc.2018.11.112Search in Google Scholar
Ji Yiming, Chen Guoqiang, Xing Tieling, et al. Development of Functional Graphene-Finished Textiles. China Dyeing & Finishing 2017; 43: 49–54.YimingJiGuoqiangChenTielingXingDevelopment of Functional Graphene-Finished TextilesChina Dyeing & Finishing2017434954Search in Google Scholar
Nadeeka DT, Ruchira NW, J Rangana P, et al. Hydrophobic Cotton Textile Surfaces Using an Amphiphilic Graphene Oxide (GO) Coating. Applied Surface Science 2015; 324: 455–463.NadeekaDTRuchiraNWJ RanganaPHydrophobic Cotton Textile Surfaces Using an Amphiphilic Graphene Oxide (GO) CoatingApplied Surface Science201532445546310.1016/j.apsusc.2014.10.148Search in Google Scholar
Ma Zhipeng. Preparation of N-halamine Treated Cotton Fabrics with Antibacterial and UV Resistance Properties. JIANGNAN University 2020.ZhipengMaPreparation of N-halamine Treated Cotton Fabrics with Antibacterial and UV Resistance PropertiesJIANGNAN University2020Search in Google Scholar