Closed network growth of fullerenes

Abstract: Tremendous advances in nanoscience have been made since the discovery of the fullerenes; however, the formation of these carbon-caged nanomaterials still remains a mystery. Here we reveal that fullerenes self-assemble through a closed network growth mechanism by incorporation of atomic carbon and C 2 . The growth processes have been elucidated through experiments that probe direct growth of fullerenes upon exposure to carbon vapour, analysed by state-of-the-art Fourier transform ion cyclotron resonance mass sp… Show more

“…Our observation of a C + 61 peak is thus consistent with the ideas of efficient single C-inclusion in the C 60 cage structure as presented in Ref. 3. However, C 61 ions were not observed directly in that experiment.…”

“…4 In the same experiment, the measured high formation rate of C 70 was rationalized as sequential absorptions of C-atoms and small carbon molecules in outer undamaged C 60 molecules, 4 similar to what was proposed in Ref. 3. Recently, we reported on covalent bond formation reactions induced in interactions between somewhat smaller clusters of C 60 and keV He 2 + ions.…”

“…We believe that this is caused by fragmentation of one or several C 60 molecules in the cluster and absorption of C atoms from such fragmentation processes by intact C 60 molecules during cluster fragmentation. In a recent study, 3 the mass spectra following laser ablation of a fullerene-graphite mixture showed clear evidence of molecular growth processes in which fullerenes larger than C 60 and with even numbers of carbon atoms were produced. As we will demonstrate below, a C + 62 peak will also appear on the side of C + 61 when we increase the cluster sizes.…”

“…However, C 61 ions were not observed directly in that experiment. 3 The narrow components of the peaks in the upper right panel of Fig. 1 are due to clusters of C 60 molecules which have been singly ionized in collisions with Ar 2 + and which remain intact during extraction and acceleration in the timeof-flight spectrometer (cf.…”

Ions colliding with clusters of fullerenes—Decay pathways and covalent bond formations

“…Our observation of a C + 61 peak is thus consistent with the ideas of efficient single C-inclusion in the C 60 cage structure as presented in Ref. 3. However, C 61 ions were not observed directly in that experiment.…”

“…4 In the same experiment, the measured high formation rate of C 70 was rationalized as sequential absorptions of C-atoms and small carbon molecules in outer undamaged C 60 molecules, 4 similar to what was proposed in Ref. 3. Recently, we reported on covalent bond formation reactions induced in interactions between somewhat smaller clusters of C 60 and keV He 2 + ions.…”

“…We believe that this is caused by fragmentation of one or several C 60 molecules in the cluster and absorption of C atoms from such fragmentation processes by intact C 60 molecules during cluster fragmentation. In a recent study, 3 the mass spectra following laser ablation of a fullerene-graphite mixture showed clear evidence of molecular growth processes in which fullerenes larger than C 60 and with even numbers of carbon atoms were produced. As we will demonstrate below, a C + 62 peak will also appear on the side of C + 61 when we increase the cluster sizes.…”

“…However, C 61 ions were not observed directly in that experiment. 3 The narrow components of the peaks in the upper right panel of Fig. 1 are due to clusters of C 60 molecules which have been singly ionized in collisions with Ar 2 + and which remain intact during extraction and acceleration in the timeof-flight spectrometer (cf.…”

Ions colliding with clusters of fullerenes—Decay pathways and covalent bond formations

“…At present, the HAC's photochemical processing is the most likely C 60 formation route in the complex circumstellar envelopes of PNe (García-Hernández et al 2012a;Bernard-Salas et al 2012;Micelotta et al 2012). Larger fullerenes may grow from pre-existing C 60 molecules (Dunk et al 2012) that may be supplied by the photochemical processing of HAC dust, opening the possibility of forming other fullerene-based molecules such as buckyonions and fullerene adducts. Indeed, fullerenes and PAHs may be mixed in the circumstellar envelopes of fullerene PNe (e.g., M 1-20) and fullerene/PAH adducts may form via Dies-Alder cycloaddition reactions (García-Hernández et al 2013).…”

Diffuse interstellar bands in fullerene planetary nebulae: the fullerenes – diffuse interstellar bands connection

Growth Mechanism