The natural process of photosynthesis is paradigmatic in converting sunlight into energy. This complicated process requires a cascade of energy- and electron-transfer events in a highly organised matrix of electron–donor, electron–acceptor and antennae units and has prompted researchers to emulate it. In fact, energy- and electron-transfer processes play a pivotal role in molecular-scale optoelectronics. In this chapter we compile a number of remarkable examples of noncovalent aggregates formed by the combination of carbon-based electroactive species (fullerenes and carbon nanotubes) hydrogen bonded with a variety of moieties. We will show that: (a) the connection of complementary electroactive species by means of H bonds in C60-based donor–acceptor ensembles is at least as efficient as that found in covalently connected systems; (b) hydrogen-bonding fullerene chemistry is a versatile concept to construct supramolecular polymers, and (c) H-bonding interactions is contributing to create very appealing carbon-nanotube-based donor–acceptor supramolecular architectures.

HERRANZ, M.A., GIACALONE, F., SANCHEZ, L., MARTIN, N. (2012). Hydrogen Bonding Donor–Acceptor Carbon Nanostructure. In F. Langa, J.F. Nierengarten (a cura di), Fullerenes: Principles and Applications 2nd Edition (pp. 192-233). Cambridge : RSC [10.1039/9781849732956-00192].

Hydrogen Bonding Donor–Acceptor Carbon Nanostructure

GIACALONE, Francesco;
2012-01-01

Abstract

The natural process of photosynthesis is paradigmatic in converting sunlight into energy. This complicated process requires a cascade of energy- and electron-transfer events in a highly organised matrix of electron–donor, electron–acceptor and antennae units and has prompted researchers to emulate it. In fact, energy- and electron-transfer processes play a pivotal role in molecular-scale optoelectronics. In this chapter we compile a number of remarkable examples of noncovalent aggregates formed by the combination of carbon-based electroactive species (fullerenes and carbon nanotubes) hydrogen bonded with a variety of moieties. We will show that: (a) the connection of complementary electroactive species by means of H bonds in C60-based donor–acceptor ensembles is at least as efficient as that found in covalently connected systems; (b) hydrogen-bonding fullerene chemistry is a versatile concept to construct supramolecular polymers, and (c) H-bonding interactions is contributing to create very appealing carbon-nanotube-based donor–acceptor supramolecular architectures.
2012
HERRANZ, M.A., GIACALONE, F., SANCHEZ, L., MARTIN, N. (2012). Hydrogen Bonding Donor–Acceptor Carbon Nanostructure. In F. Langa, J.F. Nierengarten (a cura di), Fullerenes: Principles and Applications 2nd Edition (pp. 192-233). Cambridge : RSC [10.1039/9781849732956-00192].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10447/62128
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