CuInS_2量子点制备及其对羊毛织物的改性
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摘要
利用CuInS_2量子点对羊毛织物进行整理。水相法制备的CuInS_2量子点在80℃下浸渍处理羊毛织物40 min,60℃烘干后,对整理后的羊毛织物进行表面观察、结构分析和紫外-可见光光谱及荧光光谱分析。结果表明,经CuInS_2量子点整理后的羊毛织物对紫外线的吸收谱带变宽,对紫外线的吸收性能提高。荧光光谱表明,量子点可以增加羊毛织物分子间的能量和活性,进而提高织物的物化性能。
CuInS_2 quantum dots are prepared by water phase method. The wool fabric is treated by CuInS_2 quantum dots, treating at 80 ℃ for 40 min, drying at 60 ℃. The surface, structure, ultraviolet-visible spectra and fluorescence spectra of treated wool fabric are analyzed. The results show that the wool fabrics treated with CuInS_2 quantum dots have wider absorption band and better absorption performance of ultraviolet radiation. Fluorescence spectra show that quantum dots can increase intermolecular energy and activity of wool fabrics, thereby improving the physical and chemical properties of wool fabrics.
CuInS_2 quantum dots are prepared by water phase method. The wool fabric is treated by CuInS_2 quantum dots, treating at 80 ℃ for 40 min, drying at 60 ℃. The surface, structure, ultraviolet-visible spectra and fluorescence spectra of treated wool fabric are analyzed. The results show that the wool fabrics treated with CuInS_2 quantum dots have wider absorption band and better absorption performance of ultraviolet radiation. Fluorescence spectra show that quantum dots can increase intermolecular energy and activity of wool fabrics, thereby improving the physical and chemical properties of wool fabrics.
引文
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[2]朱启海,赵长明,张逸辰等.激光电池技术进展[J].学精密工程,2016,24(10s):317-322.
[3]李正顺,岳圆圆,张艳霞等.丁胺包裹的CdSe量子点敏化的TiO2纳米晶薄膜电子转移机制[J].中国光学,2015,8(3):428-438.
[4]袁曦,郑金桔,李海波等.Mn掺杂ZnSe量子点变温发光性质研究[J].中国光学,2015,8(5):806-813.
[5]郭珉,朱秀荣,李贺军.CdTe-HgCdTe叠层太阳电池CdS窗口层透射光谱性能研究[J].红外与激光工程,2016,45(6):0621003.
[6]LI L,DAOU T J,TEXIER I.Highly luminescent CuInS2/ZnScore/shell nanocrystals:cadmium-free quantum dots for in vivoimaging.Chemistry of Materials,2009,21(12):2422-2429.
[7]TANG J,SARGENT E H.Infrared colloidal quantum dots forphotovoltaics:fundamentals and recent progress.Advanced Materials,2011,23(1):12-29.
[8]CHEN B K,ZHONG H Z,WANG W Q.Highly emissive andcolor-tunable CuInS2-based colloidal semiconductor nanocrystals:off-stoichiometry effects and improved electroluminescence performance.Advanced Functional Materials,2012,22(10):2081-2088.
[9]ZHONG H Z,LO S S,MIRKOVIC T.Noninjectiongram-scale synthesis of monodisperse pyramidal CuInS2nanocrystals and their size-dependent properties.ACS Nano,2010,4(9):5253-5262.
[10]PAN D C,AN L J,SUN Z M,et al.Synthesis of Cu-In-S ternarynanocrystals with tunable structure and composition.Journal of theAmerican Chemical Society,2008,130(17):5620-5621.
[11]PANTHANI M G,AKHAVAN V,GOODFELLOW B.Synthesisof CuInS2,CuInSe2,and Cu(InxGa1-x)Se2(CIGS)nanocrystal"inks"for printable photovoltaics.Journal of the American ChemicalSociety,2008,130(49):16770-16777.
[12]CHEN Y Y,LI S J,HUANG L J.Green and facile synthesisof water-Soluble Cu-In-S/ZnS core/shell quantum dots.InorganicChemistry,2013,52(14):7819-7821.
[13]周蓓莹,陈东,刘佳乐,等.CuInS2/ZnS核壳结构量子点的水相制备与性能研究[J].无机材料学报,2018,3(3):279-283.
[14]李润卿.有机结构波谱分析[M].天津:天津大学出版社.2002.
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