A new synthesis method for three-dimensional nanocarbons

(Nanowerk News) A team of scientists led by Kenichiro Itami, Professor and Director of the Institute of Transformative Bio-Molecules (WPI-ITbM), has developed a new method for the synthesis of three-dimensional nanocarbons with the potential to advance materials science (Nature Catalysis, "Creation of negatively curved polyaromatics enabled by annulative coupling that forms an eight-membered ring").
Three-dimensional nanocarbons, next-generation materials with superior physical characteristics which are expected to find uses in fuel cells and organic electronics, have thus far been extremely challenging to synthesize in a precise and practical fashion.
This new method uses a palladium catalyst to connect polycyclic aromatic hydrocarbons to form an octagonal structure, enabling successful three-dimensional nanocarbon molecule synthesis.
Connecting nanocarbon by catalysis to create octagonal structures
A new synthesis method creates curved octagonal structures by linking benzene rings. (Image: Issey Takahashi)
Nanocarbons, such as the fullerene (a sphere, recipient of the 1996 Nobel Prize), the carbon nanotube (a cylinder, discovered in 1991) and graphene (a sheet, recipient of the 2010 Nobel Prize) have attracted a great deal of attention as functional molecules with a variety of different properties.
Since Mackay et al. put forward their theory in 1991, a variety of periodic three-dimensional nanocarbons have been proposed. However, these have been extraordinarily difficult to synthesize.
A particular challenge is the eight-membered ring structure, which appears periodically, necessitating an efficient method for its synthesis.
To do so, Dr Itami's research team developed a new method for connecting polycyclic aromatic hydrocarbons using a palladium catalyst to produce eight-membered rings via cross-coupling, the first reaction of its type in the world.
The success of this research represents a revolutionary achievement in three-dimensional nanocarbon molecule synthesis. It is expected to lead to the discovery and elucidation of further novel properties and the development of next-generation functional materials.
Source: Institute of Transformative Bio-Molecules (ITbM), Nagoya University
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