Unique p–n Heterostructured Water‐Borne Nanoparticles Exhibiting Impressive Charge‐Separation Ability

Kim, Yu Jin; Lee, Byeongdu

doi:10.1002/cssc.201800091

Cited by 8 publications

(17 citation statements)

References 36 publications

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“…In the previous work, we used ultrasonication with 32000 Hz when the PC60 was agitated. At that time, we obtained a cluster of PC60 micelles . We hypothesized that individual PC60 micelle is more efficient to control its structure and effective to attach onto the core part of the NPs rather than the cluster formation.…”

Section: Resultsmentioning

confidence: 99%

“…In a previous work, we introduced a new surfactant, PC60, which is composed of an n‐type semiconducting fullerene molecule ([6,6]‐phenyl‐C61‐butyric acid methyl ester, PC 61 BM) grafted with a polyethylene glycol (PEG) chain . Consequently, precisely phase‐separated heterojunction NPs with a core (p‐type)‐shell (n‐type) morphology were obtained, and they showed superior charge separation properties through efficient electronic interaction between the p‐ and n‐type compounds when compared to the originally reported system.…”

Section: Introductionmentioning

confidence: 99%

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Control of Shell Morphology in p–n Heterostructured Water‐Processable Semiconductor Colloids: Toward Extremely Efficient Charge Separation

Kim

Schaller

Fry

2018

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This article describes p–n heterostructured water‐borne semiconductor naonoparticles (NPs) with unique surface structures via control of shell morphology. The shell particles, comprising PC60–[6,6]‐phenyl‐C61‐butyric acid methyl ester (PC61BM) composite, having n‐type semiconductor characteristics, notably influence the charge carrier behavior in the core–shell NPs. A one‐ or two‐phase methodology based on a PC60 surfactant‐water phase and PC61BM n‐type semiconductor‐organic phase provides highly specific control over the shell structure of the NPs, which promote their superior charge separation ability when combined with poly‐3‐hexyl‐thiophene (P3HT). Moreover, the resulting water‐borne NP exhibits shell morphology‐dependent carrier quenching and stability, which is characterized via luminescence studies paired with structural analysis. Corresponding to the results, outstanding performances of photovoltaic cells with over 5% efficiency are achieved. The results suggest that the surrounding shell environments, such as the shell structure, and its electronic charge density, are crucial in determining the overall activity of the core–shell p–n heterostructured NPs. Thus, this work provides a new protocol in the current fields of water‐based organic semiconductor colloids.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Control of Shell Morphology in p–n Heterostructured Water‐Processable Semiconductor Colloids: Toward Extremely Efficient Charge Separation

Kim

Schaller

Fry

2018

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“…In fact, PEG‐C60 has been employed to generate donor‐acceptor blend nanoparticles (NPs) formed in water through the miniemulsion process with the adequate morphology for efficient charge separation . Landfester et al .…”

Section: Eco‐friendly and Sustainable Active Layer Fabrication Processesmentioning

confidence: 99%

“…[50] Employing polymers such as PT6S and PT6N associated with water-soluble fullerenes such as the PEGylated C60 might be an efficient method to produce water-soluble active layers for eco-friendly PSC fabrication (PEG-C60, Figure 8(a)). [51] In fact, PEG-C60 has been employed to generate donoracceptor blend nanoparticles (NPs) formed in water through the miniemulsion process with the adequate morphology for efficient charge separation. [51] Landfester et al were actually the first to introduce the miniemulsion process based on nonconducting surfactants, sodium dodecyl sulfate (SDS, Figure 8(a)), for the formation of conjugated polymer-based water-dispersed NPs (Figure 8(b)).…”

Section: Can Efficient Pscs Be Produced Using Active Layers Depositedmentioning

confidence: 99%

“…[51] In fact, PEG-C60 has been employed to generate donoracceptor blend nanoparticles (NPs) formed in water through the miniemulsion process with the adequate morphology for efficient charge separation. [51] Landfester et al were actually the first to introduce the miniemulsion process based on nonconducting surfactants, sodium dodecyl sulfate (SDS, Figure 8(a)), for the formation of conjugated polymer-based water-dispersed NPs (Figure 8(b)). [52] Although most attempts to fabricate PSCs using water-processed NPs (WPNPs) lead to low PCEs (< 1 %), [53,54] a few successful examples of efficient devices can also be found in literature.…”

Section: Can Efficient Pscs Be Produced Using Active Layers Depositedmentioning

confidence: 99%

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Can Polymer Solar Cells Open the Path to Sustainable and Efficient Photovoltaic Windows Fabrication?

Vohra

2018

The Chemical Record

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Sunlight is among the most abundant energy sources available on our planet. Finding adequate solutions to properly and efficiently harvest it is of major importance to potentially solve the global energy crisis. Polymer solar cells have been introduced in the late 20th century as low‐cost and easily processed alternative to the state‐of‐the‐art silicon photovoltaics. Their power conversion efficiencies, which were initially rather low, are constantly improving and now reach values close to 15 %. As their optical properties can be easily tuned, designing active layer which absorb homogeneously throughout the visible spectrum is relatively simple. These peculiar characteristics enable the possibility to fabricate visibly transparent solar cells with high color rendering indices which can be employed as photovoltaic windows. After reviewing some of the most successful examples of polymer solar cell‐based transparent photovoltaic window fabrication, I will discuss the possibility to produce these devices in a sustainable and/or eco‐friendly manner while maintaining their performances.

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Aqueous Carbon Quantum Dot-Embedded PC60-PC₆₁BM Nanospheres for Ecological Fluorescent Printing: Contrasting Fluorescence Resonance Energy-Transfer Signals between Watermelon-like and Random Morphologies

Kim

Guo

Schaller

2019

J. Phys. Chem. Lett.

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To go beyond the PC60 surfactant structure, the double-layer micelle morphology in water motivates exploration of altered protocols to produce new morphologies. Furthermore, the low photoluminescence quantum yield of aqueous fullerene-based particles encourages high fluorescence to create a light-emitting display. With this in mind, we established new hybrid n-type nanospheres with carbon quantum dot (CQD)-embedded PC60-PC61BM particles, processed using two different protocols. The homogenizer-assisted PC60-CQD-PC61BM resulted in a watermelon-shaped spherical particle, whereas a circular morphology with randomly embedded CQDs was observed in the microwave-treated hybrids. More surprisingly, the watermelon-shaped colloid induced efficient fluorescence resonance energy transfer (FRET) between the CQD and C60 molecules of PC61BM, and the FRET-mediated emission signature diminished gradually as the stripe patterns collapsed. This phenomenon allowed different fluorescent colors in the colloidal printing film. We thereby provided the new carrier dynamics of the particle photonic activities of the developed aqueous PC60-based colloids with the possibility of ecological utilization.

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Unique p–n Heterostructured Water‐Borne Nanoparticles Exhibiting Impressive Charge‐Separation Ability

Cited by 8 publications

References 36 publications

Control of Shell Morphology in p–n Heterostructured Water‐Processable Semiconductor Colloids: Toward Extremely Efficient Charge Separation

Control of Shell Morphology in p–n Heterostructured Water‐Processable Semiconductor Colloids: Toward Extremely Efficient Charge Separation

Can Polymer Solar Cells Open the Path to Sustainable and Efficient Photovoltaic Windows Fabrication?

Aqueous Carbon Quantum Dot-Embedded PC60-PC₆₁BM Nanospheres for Ecological Fluorescent Printing: Contrasting Fluorescence Resonance Energy-Transfer Signals between Watermelon-like and Random Morphologies

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Unique p–n Heterostructured Water‐Borne Nanoparticles Exhibiting Impressive Charge‐Separation Ability

Cited by 8 publications

References 36 publications

Control of Shell Morphology in p–n Heterostructured Water‐Processable Semiconductor Colloids: Toward Extremely Efficient Charge Separation

Control of Shell Morphology in p–n Heterostructured Water‐Processable Semiconductor Colloids: Toward Extremely Efficient Charge Separation

Can Polymer Solar Cells Open the Path to Sustainable and Efficient Photovoltaic Windows Fabrication?

Aqueous Carbon Quantum Dot-Embedded PC60-PC61BM Nanospheres for Ecological Fluorescent Printing: Contrasting Fluorescence Resonance Energy-Transfer Signals between Watermelon-like and Random Morphologies

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Aqueous Carbon Quantum Dot-Embedded PC60-PC₆₁BM Nanospheres for Ecological Fluorescent Printing: Contrasting Fluorescence Resonance Energy-Transfer Signals between Watermelon-like and Random Morphologies