Self-assembled conjugated polymer spheres as fluorescent microresonators

Tabata, Ken‐ichi; Braam, Daniel; Kushida, Soh; Tong, Lewei; Kuwabara, Junpei; Kanbara, Takaki; Beckel, A.; Lorke, Axel; Yamamoto, Yohei

doi:10.1038/srep05902

Cited by 84 publications

(73 citation statements)

References 31 publications

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“…The average PL intensity ratios, r G→O and r G→R , are 1.02 and 0.79, respectively, whereas those of the reverse direction, r O→G and r R→G , are only 0. 16 Figure S11c and d), yet in the latter case, the PL intensity after propagation became very small because of the low energy transfer efficiency. Note that, according to the results on an excitation of bispheres of coupled nondoped and doped PS microspheres, the influence of the direct excitation of the adjacent sphere by the propagation of the laser beam is negligible.…”

Section: Resultsmentioning

confidence: 97%

Color-Tunable Resonant Photoluminescence and Cavity-Mediated Multistep Energy Transfer Cascade

et al. 2016

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Color-tunable resonant photoluminescence (PL) was attained from polystyrene microspheres doped with a single polymorphic fluorescent dye, boron-dipyrrin (BODIPY) 1. The color of the resonant PL depends on the assembling morphology of 1 in the microspheres, which can be selectively controlled from green to red by the initial concentration of 1 in the preparation process of the microspheres. Studies on intersphere PL propagation with multicoupled microspheres, prepared by micromanipulation technique, revealed that multistep photon transfer takes place through the microspheres, accompanying energy transfer cascade with stepwise PL color change. The intersphere energy transfer cascade is direction selective, where energy donor-to-acceptor down conversion direction is only allowed. Such cavity-mediated long-distance and multistep energy transfer will be advantageous for polymer photonics device application.

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Section: Resultsmentioning

confidence: 97%

Color-Tunable Resonant Photoluminescence and Cavity-Mediated Multistep Energy Transfer Cascade

et al. 2016

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“…According to the ellipsometry study ( Figure S12), the k value at the photoemission wavelength range of P6 was less than 0.08, which is smaller than those of the previously reported polymers (k ∼ 0.2). 19 The plots of Q max versus reciprocal radius, i.e., the curvature of the spheres, showed an approximately linear correlation (Figure 3e) because the bending radiation loss of circular resonators declines as the curvature decreases. 19,43 In addition, we checked the excitation power dependency of the PL spectra and the intensity of WGM emission peaks ( Figure S14).…”

Section: ■ Materials and Methodsmentioning

confidence: 91%

“…This value (Q max ) was 1.5-fold higher than that previously reported for the π-conjugated polymer microsphere with much larger d (Q max ∼ 600 for d = 10 μm sphere). 19 One possible reason for such high Q-factors is lower attenuation of the present microspheres. According to the ellipsometry study ( Figure S12), the k value at the photoemission wavelength range of P6 was less than 0.08, which is smaller than those of the previously reported polymers (k ∼ 0.2).…”

Section: ■ Materials and Methodsmentioning

confidence: 94%

“…25−31 However, one drawback of the fluorescent microresonators we reported is attributed to the low intrinsic photoemission properties of the copolymers, which exhibit an absolute fluorescent quantum yield (ϕ FL ) of less than 0.02 in their solid state. 19,32,33 In this article, we focus our attention on isolated conjugated polymers (ICPs). 34−40 Most ICPs show high ϕ FL even in the solid state because their π-conjugated main chains are highly isolated from one another by insulating cyclic side chains.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Interestingly, upon laser excitation of a single sphere, clear whispering gallery modes (WGM) were observed in photoemission. 19 Because the refractive indices (η) of these polymers are in the range of 1.6− 1.8, which is high enough in comparison with the refractive index of air (η air ∼ 1.0), fluorescence generated inside the microspheres is efficiently confined via total internal reflection at the polymer/air interface. As a result, sharp and periodic emission lines appear in their photoluminescence spectra with Q-factors up to 600.…”

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Whispering Gallery Resonance from Self-Assembled Microspheres of Highly Fluorescent Isolated Conjugated Polymers

et al. 2015

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Self-assembly of highly fluorescent isolated conjugated polymers (ICPs), comprising alternating phenylene moieties with an insulating cyclic side chain and different arylene moieties, was comprehensively studied. Two out of nine ICPs were identified to form well-defined spheres of 1−6 μm diameter. The degree of twisting of the main chains was found to be an important structural factor enabling formation of spheres, for which dihedral angles >50°between the neighboring arylene moieties were required. A single microsphere with high sphericity exhibited whispering gallery mode (WGM) photoemission upon excitation with a focused laser. In this emission, sharp and periodic emission lines were superimposed on a broad photoemission spectrum. The WGM spectral profiles were very sensitive to the integrity of the spherical geometries and surface smoothness, which depends on the self-assembling condition as well as the structure of the polymer backbone. Microspherical optical resonators consisting of such highly fluorescent conjugated polymers are novel. They also present advantages in that (i) there is no need for a light waveguide and fluorescent-dye doping, (ii) its high refractive index is beneficial for light confinement, and (iii) the fabrication process is simple, not requiring sophisticated, costly microfabrication technology. ■ INTRODUCTIONπ-Conjugated polymers possess charge transport, photoemission, and redox properties, which are useful for applications in electronic and optoelectronic devices such as light-emitting diodes, transistors, solar cells, and electrochromic devices. 1−6 Recently, spherical colloids formed from π-conjugated polymers have attracted attention for additional optical and biomedical applications involving fluorescence imaging, drug and gene delivery, and colloidal photonic crystals. 7−9 However, in general, π-conjugated polymers are hard to form into well-defined spheres because of their rigid and planar backbones. Thus, there have been few examples of π-conjugated polymer spheres reported so far. 8,10−16 Moreover, most of these were prepared using miniemulsion polymerization and dispersion polymerization methods.In this context, we have recently reported several π-conjugated alternating copolymers that form well-defined microspheres quantitatively via self-assembly in a thermodynamic solution process. 17,18 The slow diffusion of a polar nonsolvent vapor into a solution of a low-crystallinity polymer results in the formation of spheres with diameters in the submicrometer to several micrometers range. Interestingly, upon laser excitation of a single sphere, clear whispering gallery modes (WGM) were observed in photoemission. 19 Because the refractive indices (η) of these polymers are in the range of 1.6− 1.8, which is high enough in comparison with the refractive index of air (η air ∼ 1.0), fluorescence generated inside the microspheres is efficiently confined via total internal reflection at the polymer/air interface. As a result, sharp and periodic emission lines appear in their photolumine...

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Ultrabright Fluorescent and Lasing Microspheres from a Conjugated Polymer

Gardner

Aghajamali

Vagin

et al. 2018

Adv Funct Materials

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Fluorescent microspheres are used for biomarkers, assay substrates, chemical diagnostics, flow cytometry, and biological imaging. These applications demand the highest fluorescence intensity achievable; however, concentration quenching limits the amount of dye that can be practically incorporated in conventional fluorescent microspheres. Conjugated polymers (CPs) can be less susceptible to concentration quenching, suggesting that they can be excellent candidates for a new class of light‐emitting microspheres. Due to their long‐chain‐conjugated backbone, however, CPs can be resistant to forming smoothly curved or spherical structures. Here, strongly fluorescent CP microspheres as large as 100 µm in diameter are synthesized. Whispering gallery modes (WGMs) appear in the fluorescence spectra, and the microspheres show clear evidence of lasing above a threshold pump intensity. These conjugated polymer beads are up to 50 times larger than CP microspheres obtained by other methods, and they exceed the emission intensity of conventional fluorescent microspheres by more than an order of magnitude.

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Self-assembled conjugated polymer spheres as fluorescent microresonators

Cited by 84 publications

References 31 publications

Color-Tunable Resonant Photoluminescence and Cavity-Mediated Multistep Energy Transfer Cascade

Color-Tunable Resonant Photoluminescence and Cavity-Mediated Multistep Energy Transfer Cascade

Whispering Gallery Resonance from Self-Assembled Microspheres of Highly Fluorescent Isolated Conjugated Polymers

Ultrabright Fluorescent and Lasing Microspheres from a Conjugated Polymer

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