Organic solar cells. Supramolecular composites of porphyrins and fullerenes organized by polypeptide structures as light harvesters

Hasobe, Taku; Saito, Kenji; Kamat, Prashant V.; Troiani, Vincent; Qiu, Hengwei; Solladié, Nathalie; Kim, Kil Suk; Park, Jong Kang; Kim, Dongho; D’Souza, Francis; Fukuzumi, Shunichi

doi:10.1039/b706678c

Cited by 151 publications

(160 citation statements)

References 80 publications

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“…39(h)). 110 In this system the porphyrin was attached to the side chain of the polypeptide structure allowing for efficient organization of the electron-accepting fullerenes and porphyrins within the bulk of the photoactive layer. Although it was not clear what carrier mobilities could be obtained from this configuration, the work successfully demonstrated the importance of the molecular arrangement between the n-and p-type materials in the blended heterojunction.…”

Section: Porphyrin Polymeric Solar Cellsmentioning

confidence: 99%

Porphyrin polymers and organic frameworks

Day

Wamser

Walter

2015

Polymer International

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The versatility of porphyrins as optoelectronic or catalytic units makes them attractive elements for inclusion in functional materials. Polymers that include porphyrins have been created with a wide variety of structures and used in a wide range of applications. This review covers recent developments in the synthesis, characterization and applications of polymeric materials in which porphyrins are key components of the repeat units, including the rapidly growing area of metal-organic frameworks and related covalent organic frameworks. © 2015 Society of Chemical Industry Keywords: review; porphyrin; metal-organic framework; covalent organic framework PORPHYRINS AS FUNCTIONAL BUILDING BLOCKSThe porphyrin ring and its many structural relatives are common functional units in both natural and synthetic systems (Fig. 1). Porphyrins have a variety of properties that allow them to be useful in applications, especially their broad-ranging optoelectronic and catalytic capabilities. Furthermore, these properties are readily modulated by incorporation of various metals inside the ring or by substituent effects at various locations around the ring. In many cases, nature provides guidance for specific structure-function correlations and applications -the so-called biomimetic approaches. In nature, porphyrin (heme) units are typically embedded in a biological matrix that controls the environment of and access to the porphyrin. In synthetic systems, porphyrins in polymeric matrices have been developed in similar fashion to help control the specific application.In this review, we briefly cite previous reviews and summarize recent results regarding the synthesis, structure, properties and applications of polymeric porphyrins. We only include polymers that contain multiple porphyrin units as an integral part of the polymer, as opposed to polymeric matrices that are simply used to encapsulate individual porphyrin units. We also cover the rapidly growing field of metal-organic frameworks (MOFs) and covalent organic frameworks (COFs), where they specifically include porphyrins as a key component of the framework. Structures related to porphyrins (phthalocyanines, corroles, chlorins, etc.) and porphyrin dimers are not covered, but some porphyrin oligomers are discussed; reviews on many of these are available in the comprehensive series Handbook of Porphyrin Science.

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Section: Porphyrin Polymeric Solar Cellsmentioning

confidence: 99%

Porphyrin polymers and organic frameworks

Day

Wamser

Walter

2015

Polymer International

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“…Accordingly, the fabrication of donor-fullerene composites onto electrodes is a vital step for controlling the morphology of the composite assemblies on the electrode surface in molecular scale. Versatile methods such as Langmuir-Blodgett (LB) films [76], selfassembled monolayers (SAM) [77][78][79][80][81][82][83][84][85], layer-by-layer deposition [86,87], vacuum deposition [88,89], electrophoretic deposition [90][91][92][93][94][95][96][97][98][99], chemical adsorption, and spin coating [100][101][102][103][104][105][106][107], have been adopted to fabricate photoelectrochemical devices and solar cells.…”

Section: Photoelectrochemical Devices and Solar Cellsmentioning

confidence: 99%

Novel Electron Donor Acceptor Nanocomposites

Imahori

Guldi

Fukuzumi

2010

Chemistry of Nanocarbons

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“…Hasobe et al pointed out that there are two essential factors in the efficient photocurrent generation: one is the charge separation between the porphyrin and C 60 , and the other is the resulting hole and electron transport in the film. [32] It would be reasonable, therefore, to attribute most of C 60 molecules in the cellulose LB films to the electron carriers that receive electrons, so that C 60 mediates the electron flow from H 2 Q in the electrolyte solution to the ITO electrode via the photoexcitation of porphyrins. Figure S3 shows action spectra of the ZnPCS-C 60 LB monolayer films.…”

Section: Photocurrent Performance Of Lb Filmsmentioning

confidence: 99%

“…Another and attractive approach would be the spontaneous complexation of pristine fullerene with the sandwich-like bisporphyrin [24][25][26] and multiporphyrin [27][28][29] host molecules via a p-p interaction. Among others, Hasobe et al have capitalized on the molecular recognition between porphyrins and fullerenes to prepare organic solar cells using porphyrin-coated gold nanoparticles [30] and porphyrinpolypeptide-coated SnO 2 nanoparticles [31,32] incorporating fullerenes. Although a variety of porphyrin-fullerene p-p stacking systems have been reported, those in the monolayer at the air-water interface or in the LB films are unprecedented.…”

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confidence: 99%

Effect of Fullerene on Photocurrent Performance of 6‐O‐Porphyrin‐2,3‐di‐O‐stearoylcellulose Langmuir‐Blodgett Films

Sakakibara

Nakatsubo

2008

Macro Chemistry & Physics

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Thin films consisting of 6‐O‐porphyrin‐2,3‐di‐O‐stearoylcellulose (H2PCS) and fullerene (C60) were fabricated for anodic photocurrent generation systems by the Langmuir‐Blodgett (LB) technique. The π‐complexation between the porphyrin moiety and C60 in the LB films was investigated by means of the surface pressure (π)‐area (A) isotherms, UV‐vis, and fluorescence spectroscopy. The photocurrent density generated from the H2PCS–C60 LB monolayer films exhibited an increase with increasing the C60 proportion and reached a maximum at a mixing ratio of 1:2, yielding a quantum yield of 12.5% and an IPCE (incident photon‐to‐current efficiency) of 0.50% at a bias potential of +100 mV vs. SCE. Furthermore, the LB five‐layer films could give rise to the IPCE value of 1.5% at +100 mV without significant decline of the quantum yields, which was due to the function of C60 as an electron carrier to improve the interlayer electron transfer through each layer. These results have demonstrated a promising method for preparing the donor–acceptor systems using cellulose as a scaffold in the LB films.magnified image

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Organic solar cells. Supramolecular composites of porphyrins and fullerenes organized by polypeptide structures as light harvesters

Cited by 151 publications

References 80 publications

Porphyrin polymers and organic frameworks

Porphyrin polymers and organic frameworks

Novel Electron Donor Acceptor Nanocomposites

Effect of Fullerene on Photocurrent Performance of 6‐O‐Porphyrin‐2,3‐di‐O‐stearoylcellulose Langmuir‐Blodgett Films

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