1wileyonlinelibrary.com www.particle-journal.com www. MaterialsViews.com The "far-fi eld" effect of metal nanoparticles (NPs), when chromophores localized nearby metal NPs (typically the distance > λ /10), is an important optical effect to enhance emission in photoluminescence. The far-fi eld effect originates mainly from the interaction between origin emission and mirrorrefl ected emission, resulting in the increased irradiative rate of chromophores on the mirror-type substrate. Here, the far-fi eld effect is used to improve emission effi ciency of polymer light-emitting diodes (PLEDs). A universal performance improvement is achieved for the full visible light (red, green, blue) PLEDs, utilizing gold (Au) NPs to modify the indium tin oxide (ITO) substrates; this is shown by experimental and theoretical simulation to mainly come from the far-fi eld effect. The optimized distance, between the NPs and chromophores with visible light emission ranging from 400 to 700 nm, is 80-120 nm. Thus the scope of the far-fi eld may overlap the light-emitting profi le very well to enhance the effi ciency of optoelectronic devices. The 30-40% enhancement is obtained for different color-emitting materials through distance optimization. The far-fi eld effect is demonstrated to enhance device performance for materials in the full-visible spectral range, which extends the optoelectric applications of Au NPs.One of the most important methods to increase electroluminescence (EL) efficiency is increasing the photoluminescence (PL) effi ciency of active-layer materials, because the EL effi ciency is theoretically proportional to PL effi ciency. Driven by this motivation, scientists not only attempt different material structures of active layer but also search additional photophysical assistance during device fabrication for further enhancement. [ 10,11 ] Over the last decades, metallic nanostructures have been focused on improving the effi ciency of organic optoelectronic devices, [12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30] which is mainly based on the optical and electrical effects of metal nanoparticles (NPs), including local surface plasma-enhanced fl uorescence (LSPR), [ 12,13,17,19 ] electrical properties, [ 13,29 ] interface effect, [ 26 ] light scattering, [ 15 ] and so on.The "far-fi eld" effect of metal NPs is a very important optical effect for emission enhancement in PL besides the "nearfi eld" effect. [ 22,25,[31][32][33] The far-fi eld effect is quite different from the near-fi eld effect in working distance between metal NPs and fl uorophores. When the dye fi lm is brought into the proximity of the metal NPs-based substrate, two enhancement maximum would be observed as a function of the interlayer thickness. With the increasing of interlayer thickness, the fi rst enhancement maximum (near-fi eld effect) is observed at 5-10 nm spacer thickness. For longer distance, the enhancement of quantum yield is followed by a second maximum at 80-120 nm interlayer thicknesses, which is known as far-fi...
