Gul Rahman scite author profile

This Account presents recent advances in the design, synthesis, characterization, and potential applications of new hybrid materials based on carbon nanotube and electron donors. Fast charge separation and slow charge recombination are consistently observed in a variety of composites that contain porphyrin derivatives. The ultimate goal of using these systems to prepare practical photoelectrochemical devices is discussed, and a cell with a monochromatic efficiency of 8.5% conversion of light into current is illustrated.

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Multifunctional molecular carbon materials—from fullerenes to carbon nanotubes

Guldi

et al. 2006

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This critical review covers the timely topic of carbon nanostructures-fullerenes and carbon nanotubes-in combination with metalloporphyrins as integrative components for electron-donor-acceptor ensembles. These ensembles are typically probed in condensed media and at semi-transparent electrode surfaces. In particular, we will present a comprehensive survey of a variety of covalent (i.e., nanoconjugates) and non-covalent linkages (i.e., nanohybrids) to demonstrate how to govern/fine-tune the electronic interactions in the resulting electron-donor-acceptor ensembles. In the context of covalent bridges, different spacers will be discussed, which range from pure "insulators" (i.e., amide bonds, etc.) to sophisticated "molecular wires" (i.e., p-phenylenevinylene units, etc.). Furthermore, we will elucidate the fundamental impact that these vastly different spacers may exert on the rate, efficiency, and mechanism of short- and long-range electron transfer reactions. Additionally, a series of non-covalent motifs will be described: hydrogen bonding, complementary electrostatics, pi-pi stacking and metal coordination-to name a few. These motifs have been successfully employed by us and our collaborators en route towards novel architectures (i.e., linear structures, tubular structures, rotaxanes, catenanes, etc.) that exhibit unique and remarkable charge transfer features.

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La@C₇₂ Having a Non-IPR Carbon Cage

et al. 2006

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Gul Rahman

Carbon Nanotubes in Electron Donor−Acceptor Nanocomposites

Multifunctional molecular carbon materials—from fullerenes to carbon nanotubes

La@C₇₂ Having a Non-IPR Carbon Cage

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Gul Rahman

Carbon Nanotubes in Electron Donor−Acceptor Nanocomposites

Multifunctional molecular carbon materials—from fullerenes to carbon nanotubes

La@C72 Having a Non-IPR Carbon Cage

Contact Info

Product

Resources

About

La@C₇₂ Having a Non-IPR Carbon Cage