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研究了具有局域等离子共振特性的金纳米岛状结构阵列对高分子材料共混体系中激发复合体荧光发射特性的影响.实验结果表明,当粒子等离子共振发生在激发复合体荧光光谱区时,其荧光发射的强度得到了显著增强,且荧光寿命也得以延长.可以认为,粒子等离子共振诱发的局域场增加了激子的扩散距离,利于在相分离界面处激发复合体的形成.
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关键词:
- 金纳米岛状结构 /
- 粒子等离子共振局域场增强效应 /
- 聚合物共混体系 /
- 激发复合体
We investigate in this paper the influence of the localized plasmon resonance of gold nano-island structure on the photoluminescence of the exciplex in the polymer blends. The experimental results show that when the particle plasmon resonance overlaps the photoluminescence spectrum of the exciplex,the corresponding emission intensity is enhanced significantly. Furthermore, alonger lifetime is observed with the exciplex emission. We propose that the localized electrical field induced by the particle plasmon resonance increaseds the exciton diffusion length and thus conduces to the formation of the exciplex in the phase separation interface.-
Keywords:
- gold nano-island structure /
- particle plasmon resonance /
- enhancement of the local field /
- polymer blends
[1] Hong X,Du D D,Qiu Z R,Zhang G X 2007 Acta Phys. Sin. 56 7219 (in Chinese) [洪 昕、杜丹丹、裘祖荣、张国雄 2007 56 7219]
[2] Wu Y C,Gu Z T 2008 Acta Phys. Sin. 57 2295 (in Chinese) [吴英才、顾铮珗 2008 57 2295]
[3] Feldmann J,Scherf U,Harth E,Gügel A,Müllen K 1999 Phys. Rev. B 59 15346
[4] Hong B,Kang K A 2006 Biosens. Bioelectron. 21 1333
[5] Lukomska J,Malicka J,Gryczynski I,Leonenko Z,Lakowicz J R 2005 Biopolymers. 77 31
[6] Szmacinski H,Ray K,Lakowicz J R 2009 Anal. Biochem. 385 358
[7] Chen T,Zheng L Y,Liang F 1989 Acta Phys. Sin. 38 1755 (in Chinese) [陈 亭、郑丽羽、梁 钫 1989 38 1755]
[8] Liebermann T,Knoll W 2000 Colloids Surf. A171 115
[9] Kim S S,Na S I,Jo J,Kim D Y,Nah Y C 2008 Appl. Phys. Lett. 93 073307
[10] Hostetler M J,Wingate J E,Zhong C J,Harris J E,Vachet R W,Clark M R,Londono J D,Green S J,Stokes J J,Wignall G D,Glish G L,Porter M D,Evans N D,Murray R W 1998 Langmuir 14 17
[11] Zhang X P,Liu H M,Feng S F 2009 Nanotechnology 20 425303
[12] Morteani A C,Dhoot A S,Kim J S,Silva C,Greenham N C,Murphy C,Moons E,Ciná S,Burroughes J H,Friend R H 2003 Adv. Mater. 15 1708
[13] Morteani A C,Sreearunothai P,Herz L M,Friend R H,Silva C 2004 Phys. Rev. Lett. 92 247402
[14] Pan D H,Miao R C,Li X Y,Zhang P X 1989 Acta Phys. Sin. 38 965 (in Chinese) [潘多海、苗润才、李秀英、张鹏翔 1989 38 965]
[15] Fang Y,Wei F W,Wang Y L,Yu Y C 1994 Acta Phys. Sin. 43 555 (in Chinese) [方 炎、魏凤文、王亚利、于永澄 1994 43 555]
[16] Mayer A C,Scully S R,Hardin B E,Rowell M W,McGehee M D 2007 Mater. Today 10 28
[17] Haugeneder A,Neges M,Kallinger C,Spirkl W,Lemmer U,
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[1] Hong X,Du D D,Qiu Z R,Zhang G X 2007 Acta Phys. Sin. 56 7219 (in Chinese) [洪 昕、杜丹丹、裘祖荣、张国雄 2007 56 7219]
[2] Wu Y C,Gu Z T 2008 Acta Phys. Sin. 57 2295 (in Chinese) [吴英才、顾铮珗 2008 57 2295]
[3] Feldmann J,Scherf U,Harth E,Gügel A,Müllen K 1999 Phys. Rev. B 59 15346
[4] Hong B,Kang K A 2006 Biosens. Bioelectron. 21 1333
[5] Lukomska J,Malicka J,Gryczynski I,Leonenko Z,Lakowicz J R 2005 Biopolymers. 77 31
[6] Szmacinski H,Ray K,Lakowicz J R 2009 Anal. Biochem. 385 358
[7] Chen T,Zheng L Y,Liang F 1989 Acta Phys. Sin. 38 1755 (in Chinese) [陈 亭、郑丽羽、梁 钫 1989 38 1755]
[8] Liebermann T,Knoll W 2000 Colloids Surf. A171 115
[9] Kim S S,Na S I,Jo J,Kim D Y,Nah Y C 2008 Appl. Phys. Lett. 93 073307
[10] Hostetler M J,Wingate J E,Zhong C J,Harris J E,Vachet R W,Clark M R,Londono J D,Green S J,Stokes J J,Wignall G D,Glish G L,Porter M D,Evans N D,Murray R W 1998 Langmuir 14 17
[11] Zhang X P,Liu H M,Feng S F 2009 Nanotechnology 20 425303
[12] Morteani A C,Dhoot A S,Kim J S,Silva C,Greenham N C,Murphy C,Moons E,Ciná S,Burroughes J H,Friend R H 2003 Adv. Mater. 15 1708
[13] Morteani A C,Sreearunothai P,Herz L M,Friend R H,Silva C 2004 Phys. Rev. Lett. 92 247402
[14] Pan D H,Miao R C,Li X Y,Zhang P X 1989 Acta Phys. Sin. 38 965 (in Chinese) [潘多海、苗润才、李秀英、张鹏翔 1989 38 965]
[15] Fang Y,Wei F W,Wang Y L,Yu Y C 1994 Acta Phys. Sin. 43 555 (in Chinese) [方 炎、魏凤文、王亚利、于永澄 1994 43 555]
[16] Mayer A C,Scully S R,Hardin B E,Rowell M W,McGehee M D 2007 Mater. Today 10 28
[17] Haugeneder A,Neges M,Kallinger C,Spirkl W,Lemmer U,
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