TY - JOUR
T1 - Chemical and constitutional influences in the self-assembly of functional supramolecular hydrogen-bonded nanoscopic fibres
AU - Puigmartí-Luis, Josep
AU - Minoia, Andrea
AU - Pérez Del Pino, Ángel
AU - Ujaque, Gregori
AU - Rovira, Concepció
AU - Lledós, Agustí
AU - Lazzaroni, Roberto
AU - Amabilino, David B.
PY - 2006/12/13
Y1 - 2006/12/13
N2 - A new series of secondary amides bearing long alkyl chains with π-electron-donor cores has been synthesized and characterised, and their self-assembly upon casting at surfaces has been studied. The different supramolecular assemblies of the materials have been visualized by using atomic force microscopy (AFM) and transmission electron microscopy (TEM). It is possible to obtain well-defined fibres of these aromatic core molecules as a result of the hydrogen bonds between the amide groups. Indeed, by altering the alkyl-chain lengths, constitutions, concentrations and solvent, it is possible to form different rodlike aggregates on graphite. Aggregate sizes with a lower limit of 6-8 nm width have been reached for different amide derivatives, while others show larger aggregates with rodlike morphologies which are several micrometers in length. For one compound that forms nanofibres, doping was 'performed by using a chemical oxidant, and the resulting layer on graphite was shown to exhibit metallic-like spectroscopy curves when probed with current-sensing AFM. This technique also revealed current maps of the surface of the molecular material. Fibre formation not only takes place on the graphite surface: nanometre scale rods have been imaged by using TEM on a grid after evaporation of solutions of the compounds in chloroform. Molecular modelling proves the importance of the hydrogen bonds in the generation of the fibres, and indicates that the constitution of the molecules is vital for the formation of the desired columnar stacks, results that are consistent with the images obtained by microscopic techniques. The results show the power of noncovalent bonds in self-assembly processes that can lead to electrically conducting nanoscale supramolecular wires. © 2006 Wiley-VCH Verlag GmbH & Co. KGaA.
AB - A new series of secondary amides bearing long alkyl chains with π-electron-donor cores has been synthesized and characterised, and their self-assembly upon casting at surfaces has been studied. The different supramolecular assemblies of the materials have been visualized by using atomic force microscopy (AFM) and transmission electron microscopy (TEM). It is possible to obtain well-defined fibres of these aromatic core molecules as a result of the hydrogen bonds between the amide groups. Indeed, by altering the alkyl-chain lengths, constitutions, concentrations and solvent, it is possible to form different rodlike aggregates on graphite. Aggregate sizes with a lower limit of 6-8 nm width have been reached for different amide derivatives, while others show larger aggregates with rodlike morphologies which are several micrometers in length. For one compound that forms nanofibres, doping was 'performed by using a chemical oxidant, and the resulting layer on graphite was shown to exhibit metallic-like spectroscopy curves when probed with current-sensing AFM. This technique also revealed current maps of the surface of the molecular material. Fibre formation not only takes place on the graphite surface: nanometre scale rods have been imaged by using TEM on a grid after evaporation of solutions of the compounds in chloroform. Molecular modelling proves the importance of the hydrogen bonds in the generation of the fibres, and indicates that the constitution of the molecules is vital for the formation of the desired columnar stacks, results that are consistent with the images obtained by microscopic techniques. The results show the power of noncovalent bonds in self-assembly processes that can lead to electrically conducting nanoscale supramolecular wires. © 2006 Wiley-VCH Verlag GmbH & Co. KGaA.
KW - Hydrogen bonds
KW - Isomers
KW - pi interactions
KW - Supramolecular assembly
KW - Tetrathiafulvalene
U2 - 10.1002/chem.200601089
DO - 10.1002/chem.200601089
M3 - Article
SN - 0947-6539
VL - 12
SP - 9161
EP - 9175
JO - Chemistry - A European Journal
JF - Chemistry - A European Journal
IS - 36
ER -