Journal of Materials Chemistry Blog

In this Hot Paper Andrew C. Grimsdale and co-workers at Nanyang Technological University and University of Liverpool prepare 3D supramolecular networks using Zn(II) coordination of the tetraphenylmethane-based p-type and n-type molecules bearing four terpyridine ligands. The team also demonstrate that metal–ligand mediated self-assembly can be used to make two component systems in which the optical properties can be tuned by selection of the units.

New 3D supramolecular Zn(II)-coordinated self-assembled organic networks: Zheng Bang Lim, Hairong Li, Shuangyong Sun, Jun Yan Lek, Abbie Trewin, Yeng Ming Lam and Andrew C. Grimsdale, J. Mater. Chem., 2012, 22, 6218-6231

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Controlling the structure of cholesteric helices holds great potential for developing stimuli-responsive materials. For instance inversion of a cholesteric helix is associated with inversion of the circular polarization of the light it reflects. This Hot Feature Article reviews recent achievements in inducing, controlling and understanding helix inversion in cholesteric liquid crystals. Read the article for free until 17^th May.

Controlling chirality with helix inversion in cholesteric liquid crystals: Nathalie Katsonis, Emmanuelle Lacaze and Alberta Ferrarini, J. Mater. Chem., 2012, 22, 7088-7097

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Halogen bonding has emerged as a powerful tool for self-assembly due to its highly directional and hydrophobic nature. In spite of the number of one dimensional or infinite linear networks assembled by 1,4-DITFB with different acceptors, no example describing C–I π halogen bonding phosphorescence crystal has been reported. In this hot article Wei Jun Jin and colleagues at Beijing Normal University, China, describe a new organic phosphorescent co-crystal material based on 1,4-DITFB and carbazole. The team says that The halogen bonding of 1,4-DITFB with carbazole is selective, and the co-crystal microparticle suspension displays strong phosphorescence. Wei Jun Jin and the team say this is the first report of a phosphorescent co-crystal assembled by weak C–I π interaction. Read the article for free until 30^th April.

Phosphorescent co-crystal assembled by 1,4-diiodotetrafluorobenzene with carbazole based on C–I π halogen bonding: Hai Yue Gao, Qian Jin Shen, Xiao Ran Zhao, Xiao Qing Yan, Xue Pang and Wei Jun Jin, J. Mater. Chem., 2012, 22, 5336-5343.

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The giant dielectric permittivity of detonation-produced nanodiamond is caused by water, say scientists from Russia and the UK. Nanodiamonds can be produced cheaply from explosions. The team found that just by adding water to the nanodiamonds, the materials see a huge increase in electronic properties, which means that they could be used for many electronic applications, such as in high performance capacitors for microelectronics and developing large-scale capacitance-based energy storage devices that are in demand in the quest for green energy technology. Read the article for free until 26th April.

Paper: Giant dielectric permittivity of detonation-produced nanodiamond is caused by water
Stepan Segreevich Batsanov and A Batsanov,
J. Mater. Chem., 2012, DOI: 10.1039/C2JM30836C

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Scientists in China and Canada have used high intensity ultrasound to change the shape of polymers for use in surgical implants. Polymer shape recovery has been employed before using light and heat as external stimuli but not with ultrasound, which has much greater spatial and temporal control as well as being able to penetrate much deeper into body tissue.

In addition to being able to generate different shapes, the ultrasound can be used to simultaneously induce drug release from the polymer. This has a potential application in minimally invasive surgical techniques. Read this article for free until the 25th April.

Communication: Spatial and temporal control of shape memory polymers and simultaneous drug release using high intensity focused ultrasound
Guo Li, Guoxia Fei, Hesheng Xia, Jianjun Han and Yue Zhao
J. Mater. Chem., 2012, DOI: 10.1039/C2JM30848G (Advance Article)

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