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The graphene and nanoparticles composites have novel optical and electrical properties. They are widely used in the fields of information sensing, photoelectric conversion and medical diagnosis. Graphene has excellent photoelectric properties and can regulate the random laser properties, but the current composite process of graphene with special structures and metal nanostructures is complicated. Thus, there is still a challenge to effectively reducing the threshold of random laser by using graphene. In this work, the Au/graphene structure is prepared by convenient chemical reduction and adsorption method, and the dye DCJTB is used as the gain medium to form the film by spin coating. The random laser properties of Au nanoparticles and Au/graphene structure are studied, and the mechanism of graphene is analyzed. The results show that the transmission peak of Au/graphene composite is near the photoluminescence peak of gain medium, which promotes the energy level transition of dye molecules. With the addition of graphene into the same gain medium, the scattering frequency of photons in the disordered medium increases, resulting in the enhancement of surface plasmon resonance. The scattering effect and the surface plasmon resonance effect cooperate with each other, showing good random laser threshold, which is reduced from 3.4 μJ/mm2 to 2.8 μJ/mm2. Repeatability and high quality of maser are obtained by repetitively measuring the same sample, showing that the lasing sample has good repeatability and high quality. This study plays a certain role in promoting the application of random laser and realizing the high-performance optoelectronic devices.
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Keywords:
- random laser /
- surface plasmon resonance /
- graphene /
- Au nanoparticles
[1] Soest G V, Lagendijk A 2002 Phys. Rev. E 65 047601
Google Scholar
[2] Soest G V, Poelwijk F J, Lagendijk A 2002 Phys. Rev. E 65 046603
Google Scholar
[3] Wang Y, Duan Z J, Qiu Z, Zhang P, Wu J W, Zhang D K, Xiang T X 2017 Sci. Rep. 7 8385
Google Scholar
[4] Chen H, Gao S H, Zhang M J, Zhang J Z, Qiao L J, Wang T, Gao F, Hu X X, Li S C, Zhu Y C 2020 Sensors 20 6122
Google Scholar
[5] Wiersma, Diederik S 2008 Nat. Phys. 4 359
Google Scholar
[6] Rashidi M, Haggren T, Su Z, Jagadish C, Tan H H 2021 Nano. Lett. 21 3901
Google Scholar
[7] Siva G V, Nair R V, Krishnan S R, Vijayan C 2017 Opt. Lett. 42 5002
Google Scholar
[8] Haddaw S F, Humud H R, Hamidi S M 2020 Optik 207 164482
Google Scholar
[9] Xia J Y, He J J, Xie K, Zhang X J, Hu L, Li Y, Chen X X, Ma J J, Wen J X, Chen J J, Pan Q S, Zhang J X, Vatnik I D, Churkin D, Hu Z J 2019 Annalen der Physik 531 1900066
Google Scholar
[10] Li Y X, Xie K, Zhang X J, Hu Z J, Ma J J, Chen X X, Zhang J X, Liu Z M, Chen D 2020 Photonic. Sens. 10 254
Google Scholar
[11] Chen Z X, Zhang Y J, Chu S, Sun R, Wang J, Chen J P, Wei B, Zhang X, Zhou W H, Shi Y M 2020 ACS Appl. Mater. Interfaces 12 23323
Google Scholar
[12] Yuan F L, Xi Z F, Shi X Y, Li Y C, Li X H, Wang Z N, Fa L Z, Yang S H 2019 Adv. Opt. Mater. 7 1801202
Google Scholar
[13] Gayathri R, Monika K, Murukeshan V M, Vijayan C 2021 Opt. Laser. Technol. 139 106959
Google Scholar
[14] Shi X Y, Bian Y X, Tong J H, Liu D H, Zhou J, Wang Z N 2020 Opt. Express 28 13576
Google Scholar
[15] Wan Y, Deng L G 2019 Opt. Express 27 27103
Google Scholar
[16] Shi X Y, Chang Q, Bian Y X, Cui H B, Wang Z N 2019 ACS Photonics 6 2245
Google Scholar
[17] Wan Y, An Y, Deng L G 2017 Sci. Rep. 7 16185
Google Scholar
[18] Zhang R, Knitter S, Liew S F, Omenetto F G, Reinhard B M, Cao H, Negro D L 2016 Appl. Phys. Lett. 108 011103
Google Scholar
[19] Long L, He D, Bao W, Feng M, Chen S 2017 J. Alloys. Compd. 693 876
Google Scholar
[20] Zhai T, Zhang X, Pang Z, Su X, Liu H, Feng S, Wang L 2011 Nano. Lett. 11 4295
Google Scholar
[21] Zhang N M, Ning S Y, Dai K, Zhang Y F, Wu Y, Yuan F, Zhang F H 2020 Opt. Mater. Express 10 1204
Google Scholar
[22] Marini A, Garcia D A F J 2016 Phys. Rev. Lett. 116 217401
Google Scholar
[23] Pradip K R, Golam H, Lin H, Liao Y M, Lu C H, Chen K H, Chen L H, Shi W H, Liang C T, Chen Y F 2018 Adv. Opt. Mater. 6 1800382
Google Scholar
[24] Lee J, Kim J, Ahmed S R, Zhou H 2014 ACS Appl. Mater. Interfaces 6 21380
Google Scholar
[25] Shi J Y, Chan C Y, Pang Y T, Ye W W, Tian F, Jing L Y, Zhang Y, Yang M 2015 Biosens. Bioelectron. 67 595
Google Scholar
[26] Lü H, Lan Y Y, Zhao Q L, Wang X, Zhang S Y, Teng L H, Tam W Y 2018 Appl. Phys. B 124 227
Google Scholar
[27] Ma H R, Lü H, Wang X 2020 Optik 223 165567
Google Scholar
[28] Bae S, Kim H, Lee Y, Xu X, Park J S, Zheng Y, Balakrishnan J, Lei T, Kim R T, Song Y 2010 Nat. Nanotechnol. 5 574
Google Scholar
[29] Shen T, Li Z, Jiang Y, Luo Z G 2019 Funct. Mater. Lett. 12 1950028
Google Scholar
[30] Ning S, Dong H, Zhang N, Zhao J, Ding L 2016 Opt. Mater. Express 6 3725
Google Scholar
[31] Tao A, Sinsermsuksakul P, Yang P D 2007 Nat. Nanotechnol. 2 435
Google Scholar
[32] Zhang Z Y, Liu L H, Wang W, Cao Z J, Martinelli A, Wang E G, Cao Y, Chen J N, Yurgens A, Sun J 2016 Adv. Opt. Mater. 4 2021
Google Scholar
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图 1 (a) Au纳米颗粒激射样品模型图; (b) Au/石墨烯激射样品模型图
Figure 1. Model of (a) Au NPs and (b) Au/Graphene lasing sample.
图 2 石墨烯的(a) TEM图、(b) SEM图、(c)红外光谱图和(d)拉曼光谱图
Figure 2. (a) TEM image, (b) SEM image, (c) IR spectra, and (d) Raman spectra of Graphene.
图 3 (a) Au纳米颗粒的TEM图; (b) Au纳米颗粒的粒径分布统计图; (c) Au/石墨烯的TEM图; (d) Au纳米颗粒和Au/石墨烯的透射光谱以及DCJTB染料光致发光光谱
Figure 3. (a) TEM images of Au NPs; (b) the corresponding size distribution of Au NPs; (c) TEM images of Au/Graphene; (d) transmission spectra of Au NPs, Au/Graphene and photoluminescence spectra of DCJTB.
图 4 (a) Au纳米颗粒激射样品在不同泵浦能量下的光致发光光谱; (b) 激射峰值与泵浦能量的关系图
Figure 4. (a) Lasing spectra of Au NPs samples at different pump energies; (b) the output intensity of the random lasing as a function of the pump energy.
图 5 (a) Au/石墨烯激射样品在不同泵浦能量下的光致发光光谱; (b)激射峰强度值与泵浦能量的关系图
Figure 5. (a) Lasing spectra of Au/Graphene samples at different pump energies; (b) the output intensity of the random lasing as a function of the pump energy.
图 6 Au纳米颗粒和Au/石墨烯激射样品激射峰值和半高宽与泵浦能量的关系图(插图为样品在泵浦下的光学图像)
Figure 6. Intensity and FWHM of lasing peak as a function of the pump energy of Au Nps and Au/Graphene. The inset is the optical image under the pumping.
图 7 (a) Au纳米颗粒散射模型图; (b) Au/石墨烯复合结构散射模型图
Figure 7. (a) Scattering model diagram of Au NPs; (b) scattering model diagram of Au/Graphene.
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[1] Soest G V, Lagendijk A 2002 Phys. Rev. E 65 047601
Google Scholar
[2] Soest G V, Poelwijk F J, Lagendijk A 2002 Phys. Rev. E 65 046603
Google Scholar
[3] Wang Y, Duan Z J, Qiu Z, Zhang P, Wu J W, Zhang D K, Xiang T X 2017 Sci. Rep. 7 8385
Google Scholar
[4] Chen H, Gao S H, Zhang M J, Zhang J Z, Qiao L J, Wang T, Gao F, Hu X X, Li S C, Zhu Y C 2020 Sensors 20 6122
Google Scholar
[5] Wiersma, Diederik S 2008 Nat. Phys. 4 359
Google Scholar
[6] Rashidi M, Haggren T, Su Z, Jagadish C, Tan H H 2021 Nano. Lett. 21 3901
Google Scholar
[7] Siva G V, Nair R V, Krishnan S R, Vijayan C 2017 Opt. Lett. 42 5002
Google Scholar
[8] Haddaw S F, Humud H R, Hamidi S M 2020 Optik 207 164482
Google Scholar
[9] Xia J Y, He J J, Xie K, Zhang X J, Hu L, Li Y, Chen X X, Ma J J, Wen J X, Chen J J, Pan Q S, Zhang J X, Vatnik I D, Churkin D, Hu Z J 2019 Annalen der Physik 531 1900066
Google Scholar
[10] Li Y X, Xie K, Zhang X J, Hu Z J, Ma J J, Chen X X, Zhang J X, Liu Z M, Chen D 2020 Photonic. Sens. 10 254
Google Scholar
[11] Chen Z X, Zhang Y J, Chu S, Sun R, Wang J, Chen J P, Wei B, Zhang X, Zhou W H, Shi Y M 2020 ACS Appl. Mater. Interfaces 12 23323
Google Scholar
[12] Yuan F L, Xi Z F, Shi X Y, Li Y C, Li X H, Wang Z N, Fa L Z, Yang S H 2019 Adv. Opt. Mater. 7 1801202
Google Scholar
[13] Gayathri R, Monika K, Murukeshan V M, Vijayan C 2021 Opt. Laser. Technol. 139 106959
Google Scholar
[14] Shi X Y, Bian Y X, Tong J H, Liu D H, Zhou J, Wang Z N 2020 Opt. Express 28 13576
Google Scholar
[15] Wan Y, Deng L G 2019 Opt. Express 27 27103
Google Scholar
[16] Shi X Y, Chang Q, Bian Y X, Cui H B, Wang Z N 2019 ACS Photonics 6 2245
Google Scholar
[17] Wan Y, An Y, Deng L G 2017 Sci. Rep. 7 16185
Google Scholar
[18] Zhang R, Knitter S, Liew S F, Omenetto F G, Reinhard B M, Cao H, Negro D L 2016 Appl. Phys. Lett. 108 011103
Google Scholar
[19] Long L, He D, Bao W, Feng M, Chen S 2017 J. Alloys. Compd. 693 876
Google Scholar
[20] Zhai T, Zhang X, Pang Z, Su X, Liu H, Feng S, Wang L 2011 Nano. Lett. 11 4295
Google Scholar
[21] Zhang N M, Ning S Y, Dai K, Zhang Y F, Wu Y, Yuan F, Zhang F H 2020 Opt. Mater. Express 10 1204
Google Scholar
[22] Marini A, Garcia D A F J 2016 Phys. Rev. Lett. 116 217401
Google Scholar
[23] Pradip K R, Golam H, Lin H, Liao Y M, Lu C H, Chen K H, Chen L H, Shi W H, Liang C T, Chen Y F 2018 Adv. Opt. Mater. 6 1800382
Google Scholar
[24] Lee J, Kim J, Ahmed S R, Zhou H 2014 ACS Appl. Mater. Interfaces 6 21380
Google Scholar
[25] Shi J Y, Chan C Y, Pang Y T, Ye W W, Tian F, Jing L Y, Zhang Y, Yang M 2015 Biosens. Bioelectron. 67 595
Google Scholar
[26] Lü H, Lan Y Y, Zhao Q L, Wang X, Zhang S Y, Teng L H, Tam W Y 2018 Appl. Phys. B 124 227
Google Scholar
[27] Ma H R, Lü H, Wang X 2020 Optik 223 165567
Google Scholar
[28] Bae S, Kim H, Lee Y, Xu X, Park J S, Zheng Y, Balakrishnan J, Lei T, Kim R T, Song Y 2010 Nat. Nanotechnol. 5 574
Google Scholar
[29] Shen T, Li Z, Jiang Y, Luo Z G 2019 Funct. Mater. Lett. 12 1950028
Google Scholar
[30] Ning S, Dong H, Zhang N, Zhao J, Ding L 2016 Opt. Mater. Express 6 3725
Google Scholar
[31] Tao A, Sinsermsuksakul P, Yang P D 2007 Nat. Nanotechnol. 2 435
Google Scholar
[32] Zhang Z Y, Liu L H, Wang W, Cao Z J, Martinelli A, Wang E G, Cao Y, Chen J N, Yurgens A, Sun J 2016 Adv. Opt. Mater. 4 2021
Google Scholar
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