PCCP Blog

When a river comes up against an obstacle, it will split and flow around it before joining up again, thereby forming a central island. Similarly, carbon nanotubes can be grown to split apart and then re-join through the judicious use of metal catalysts. The authors of this communication, Hasegawa and Kohno, identified this phenomenon and coined the term ‘origami mechanism’ to describe it.

My river analogy is, however, a rather simplistic take on what they found. In order to draw a more accurate comparison I must turn to tree limbs. Imagine a branch with a linear split; there will be a hole in the middle, flanked by bare timber, and the bark will be effectively split into two halves with clearly defined edges. This would be equivalent to the carbon nanotube splitting into two ribbons with terminal edges, before reforming into an entire nanotube, as one might expect to observe.

However, this does not entirely tally with what Hasegawa and Kohno actually found. Their findings align more closely with the example of a wisteria, which has co-dominant stems, which grow apart and then re-fuse as the plant twists around itself as it grows. The difference here is that each of the stems, whilst apart, still retains a full covering of bark, as it is a distinct branch. Indeed, the authors found that the nanoribbons take the form of entire flattened nanotubes before they join up again.

Of course, the reality is more complex still, and you can’t beat reading about it in the authors’ own words, which incidentally, I strongly encourage you to do.

Previously unknown carbon allotropes have been predicted by scientists exploring their links with well-known network topologies. The new structures are highly stable and transparent, some with larger optical band gaps than diamond.

Advanced computational techniques are leading the search for new forms of carbon and other group 14 elements. Now, Davide Proserpio from the University of Milan, Italy, and co-workers, have shown that fundamental network descriptors known about and catalogued for many years can help predict as well as classify and compare allotropes.

Interested to know more?

Read the full article in Chemistry World by Jonathan Midgley.

Take a look at the original Open Access research article:

From zeolite nets to sp³ carbon allotropes: a topology-based multiscale theoretical study
Igor A. Baburin, Davide M. Proserpio, Vladimir A. Saleev and Alexandra V. Shipilova
Phys. Chem. Chem. Phys., 2015, DOI: 10.1039/C4CP04569F

Take two bodies of water whose initial characteristics are identical, except for their temperature. Measure how long it takes these two bodies of water to cool to the same specified lower temperature. Explain why the initially hotter water apparently cools faster.

Alright, so it’s a bit more complicated than that, with precise experimental parameters that must be adhered to, but the essence of the problem remains the same. There appears to be a difference in the relative rates at which different bodies of water cool depending on their starting temperatures. The Mpemba effect (as it is often known) may sound simple, but it is a phenomenon that is often disputed, deceptively difficult to analyse, has many proffered explanations and a historical pedigree going back to Aristotle. A few years ago the RSC even held a competition to try to settle the matter and reach a consensus of opinion. Yet despite the declaration of a winner, apparently not everybody agreed that the question was quite settled once and for all.

Now, Zhang et al. are throwing their hat into the ring with a new answer. They say that they’ve approached the problem from an unusual angle, and present new quantitative evidence to support their argument. So have they finally cracked it, or is this just the latest in a long line of possible explanations that extends back over thousands of years? With a topic as divisive as this, I’m not placing any bets just yet.

Read the original manuscript online now!

Hydrogen-bond memory and water-skin supersolidity resolving the Mpemba paradox

Xi Zhang, Yongli Huang, Zengsheng Ma, Yichun Zhou, Ji Zhou, Weitao Zheng, Qing Jiang and Chang Q. Sun

Phys. Chem. Chem. Phys., 2014, DOI: 10.1039/C4CP03669G