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目前对于单金属纳米材料的研究已经非常广泛,但是合金纳米材料的相关研究还有待进一步开发。如何在降低成本、简化制备方法的基础上,对合金纳米材料进行更深入的探索是目前的一个研究方向。提出了一种利用磁控溅射结合真空退火制备铜银合金纳米岛结构的新方法。通过控制溅射时间、溅射顺序和退火温度,可实现不同形貌、不同光谱响应特性的铜银合金纳米岛结构的可控制备。选用制备的铜银合金纳米岛作为CdSe量子点荧光增强基底。实验结果表明,铜银合金纳米岛基底的量子点样品的荧光强度相较于单纯的量子点样品有显著增强,增幅达到4.71倍,荧光寿命缩短了7.9 ns。提出的铜银合金纳米岛制备方法具有成本低、速度快、重复性好等优点,为铜银合金纳米结构的研究提供了一种新的思路和方法,为等离激元微纳米结构在多领域应用和产业化提供了参考。
Abstract:At present, the research on monometallic nanomaterials is already quite extensive, but the related research of alloy nanomaterials needs to be further developed. On the basis of reducing the cost and simplifying the preparation method, it is a current research direction to explore the alloy nanomaterials more deeply. A novel method for preparing Cu-Ag alloy nanoisland structures by magnetron sputtering combined with vacuum annealing was presented. By controlling the sputtering time, sputtering sequence and annealing temperature, the controllable preparation of Cu-Ag alloy nanoisland structures with different morphologies and spectral response characteristics can be achieved. The prepared Cu-Ag alloy nanoislands were selected as the fluorescence enhanced substrate for CdSe quantum dots. Experimental results show that the fluorescence intensity of quantum dot sample with the Cu-Ag alloy nanoisland as substrate is significantly enhanced compared with the simple quantum dot sample, which the increase amplitude reaches 4.71 times and the fluorescence lifetime is shortened by 7.9 ns. The proposed preparation method for Cu-Ag alloy nanoislands has advantages such as low cost, fast speed and good repeatability, providing a new idea and method for the research of Cu-Ag alloy nanostructures and references for the application and industrialization of plasmon micro-nanostructures in various fields.
[1] DONG J,ZHANG Z L,ZHENG H R,et al.Recent progress on plasmon-enhanced fluorescence[J].Nanophoto-nics,2015,4(4):472-490.
[2] 吕凤婷,郑海荣,房喻.表面增强荧光研究进展[J].化学进展,2007,19(2/3):256-266.Lü F T,ZHENG H R,FANG Y.Studies of surface-enhanced fluorescence[J].Progress in Chemistry,2007,19(2/3):256-266.
[3] 徐良敏,张正龙,蔡晓燕,等.金属表面荧光增强的物理增强机制[J].发光学报,2009,30(3):373-378.XU L M,ZHANG Z L,CAI X Y,et al.Physical mechanisms of fluorescence enhancement at metal surface[J].Chinese Journal of Luminescence,2009,30(3):373-378.
[4] HE W,SUN X Y,LIU B,et al.A label-free "SEF-FRET" fluorescent sensing platform for ultrasensitive DNA detection based on AgNPs SAMs[J].Talanta,2019,205:120072.
[5] CAO H J,SHANG Z B,CAO H W,et al.An efficient and low-cost surface-enhanced fluorescence substrate for trace detection of melamine in milk samples[J].Optik,2022,268:169856.
[6] BADSHAH M A,KOH N Y,ZIA A W,et al.Recent developments in plasmonic nanostructures for metal enhanced fluorescence-based biosensing[J].Nanomaterials,2020,10(9):1749.
[7] LI Y,HAO Z S,CAO H J,et al.Study on annealed graphene oxide nano-sheets for improving the surface enhanced fluorescence of silver nanoparticles[J].Optics & Laser Technology,2023,160:109054.
[8] PENG L,LIU Y,ZHANG J,et al.Surface plasmon-enhanced NIR-II fluorescence in a multilayer nanoprobe for through-skull mouse brain imaging[J].ACS Applied Materials & Interfaces,2022,14(34):38575-38583.
[9] GU C,JIA A B,ZHANG Y M,et al.Emerging electrochromic materials and devices for future displays[J].Chemical Reviews,2022,122(18):14679-14721.
[10] RADCHANKA A,HRYBOUSKAYA V,IODCHIK A,et al.Zeta potential-based control of CdSe/ZnS quantum dot photoluminescence[J].Journal of Physical Chemistry Letters,2022,13(22):4912-4917.
[11] DAI C H,LIU Y Q,WEI D C.Two-dimensional field-effect transistor sensors:the road toward commercialization[J].Chemical Reviews,2022,122(11):10319-10392.
[12] WANG H Y,GUO Y Y,HAO H X,et al.Bright CdSe/CdS quantum dot light-emitting diodes with modulated carrier dynamics via the local kirchhoff law[J].ACS Applied Materials & Interfaces,2021,13(47):56476-56484.
[13] PENG M,BAI Z C,ZHANG Y,et al.Protein detection chip based on quantum dot fluorescence quenching method[J].Laser & Optoelectronics Progress,2019,56(6):062601.
[14] LI Y,TAO L,GAN F W,et al.Strain-field-induced energy tuning for self-assembled quantum dots-based single-photon sources interfacing atomic transitions[J].Acta Photonica Sinica,2019,48:827001.
[15] CAI C F,WANG X Y,LING L,et al.Photoluminescence enhancement in wide spectral range excitation in CsPbBr3 nanocrystal/Ag nanostructure via surface plasmon coupling[J].Optics Letters,2019,44(3):658-661.
[16] TROTSIUK L,MURAVITSKAYA A,KULAKOVICH O,et al.Plasmon-enhanced fluorescence in gold nanorod-quantum dot coupled systems[J].Nanotechnology,2019,31(10):105201.
[17] SU Q,JIANG C,GOU D M,et al.Surface plasmon-assisted fluorescence enhancing and quenching:from theory to application[J].ACS Applied Bio Materials,2021,4(6):4684-4705.
[18] CHEN Y Q,HU Y Q,ZHAO J Y,et al.Topology optimization-based inverse design of plasmonic nanodimer with maximum near-field enhancement[J].Advanced Functio-nal Materials,2020,30(23):2000642.
[19] ZHANG X G,ZHANG X L,LUO C L,et al.Volume-enhanced Raman scattering detection of viruses[J].Small,2019,15(11):1805516.
[20] ZHU L L,GAO M M,PEH C K N,et al.Solar-driven photothermal nanostructured materials designs and prere-quisites for evaporation and catalysis applications[J].Materials Horizons,2018,5(3):323-343.
[21] HU H L,DUAN H G,YANG J K W,et al.Plasmon-modulated photoluminescence of individual gold nanostructures[J].ACS Nano,2012,6(11):10147-10155.
[22] CUI X M,QIN F,RUAN Q F,et al.Circular gold nanodisks with synthetically tunable diameters and thicknesses[J].Advanced Functional Materials,2018,28(11):1705516.
[23] LIU Y M,HU Y,ZHANG J.Few-layer graphene-encapsulated metal nanoparticles for surface-enhanced Raman spectroscopy[J].Journal of Physical Chemistry:C,2014,118(17):8993-8998.
[24] ZHANG X F,KONG X M,LV Z P,et al.Bifunctional quantum dot-decorated Ag@SiO2 nanostructures for simultaneous immunoassays of surface-enhanced Raman scatte-ring (SERS) and surface-enhanced fluorescence (SEF)[J].Journal of Materials Chemistry:B,2013,1(16):2198-2204.
[25] CHEN Y C,MUNECHIKA K,GINGER D S.Dependence of fluorescence intensity on the spectral overlap between fluorophores and plasmon resonant single silver nanoparticles[J].Nano Letters,2007,7(3):690-696.
基本信息:
DOI:10.13250/j.cnki.wndz.24080303
中图分类号:TB383.1
引用信息:
[1]张简玙,张健.铜银合金纳米岛的可控制备及其量子点荧光增强性能[J].微纳电子技术,2024,61(08):141-149.DOI:10.13250/j.cnki.wndz.24080303.
基金信息:
国家自然科学基金青年科学基金(61905016)
2024-08-15
2024-08-15