Theoretical Insights into Chirality‐Controlled SWCNT Growth from a Cycloparaphenylene Template

A self‐assembly mechanism for low‐temperature SWCNT growth from a [6]cycloparaphenylene ([6]CPP) precursor via ethynyl (C₂H) radical addition is presented, based on non‐equilibrium quantum chemical molecular dynamics (QM/MD) simulations and density functional theory (DFT) calculations. This mechanism, which maintains the (6,6) armchair chirality of a SWCNT fragment throughout the growth process, is energetically more favorable than a previously proposed Diels–Alder‐based growth mechanisms [E. H. Fort, et al., J. Mater. Chem. 2011 , 21, 1373]. QM/MD simulations and DFT calculations show that C₂H radicals play dual roles during SWCNT growth, by abstracting hydrogen from the SWCNT fragment and providing the carbon source necessary for growth itself. Simulations demonstrate that chirality‐controlled SWCNT growth from macrocyclic hydrocarbon seed molecules with pre‐selected edge structure can be accomplished when the reaction conditions are carefully selected for hydrogen abstraction by radical species during the growth process.     

Cover Picture: Ab Initio Calculation of Parity‐Violating Chemical Shifts in NMR Spectra of Chiral Molecules (ChemPhysChem 4/2003)

The cover picture shows an intriguing effect in molecular systems, which is caused by the parity‐violating weak interactions: The chemical shifts of magnetic nuclei are predicted to differ for the two enantiomers of a chiral compound! While in the R enantiomer the nucleus (red) of the yellow center gives rise to the red NMR signal, the corresponding nucleus of the S enantiomer (green) is expected to absorb at a slightly different frequency. The ab initio approach presented by Laubender and Berger on pp. 395–399 allows for a prediction of the resulting parity‐violating line splitting (shown in the black curve) and for the identification of molecular candidates that are well‐suited to the first successful measurement of parity‐violating effects in molecules.     

Extraction of (9,8) Single‐Walled Carbon Nanotubes by Fluorene‐Based Polymers

Selective polymer wrapping is a promising approach to obtain high‐chiral‐purity single‐walled carbon nanotubes (SWCNTs) needed in technical applications and scientific studies. We showed that among three fluorene‐based polymers with different side‐chain lengths and backbones, poly[(9,9‐dihexylfluorenyl‐2,7‐diyl)‐co‐(9,10‐anthracene)] (PFH‐A) can selectively extract SWCNTs synthesized from the CoSO₄/SiO₂ catalyst, which results in enrichment of 78.3 % (9,8) and 12.2 % (9,7) nanotubes among all semiconducting species. These high‐chiral‐purity SWCNTs may find potential applications in electronics, optoelectronics, and photovoltaics. Furthermore, molecular dynamics simulations suggest that the extraction selectivity of PFH‐A relates to the bending and alignment of its alkyl chains and the twisting of its two aromatic backbone units (biphenyl and anthracene) relative to SWCNTs. The strong π–π interaction between polymers and SWCNTs would increase the extraction yield, but it is not beneficial for chiral selectivity. Our findings suggest that the matching between the curvature of SWCNTs and the flexibility of the polymer side chains and the aromatic backbone units is essential in designing novel polymers for selective extraction of (n,m) species.