CrystEngComm Blog

The fractal crystal pattern, transferred onto a dress, won the researchers a prize at a design competition

Guoqing Zhang, Xuepeng Zhang and their team at the University of Science and Technology of China first intended to construct a series of organic ligands for water-based acrylic paints. By performing a routine Claisen condensation reaction between a ketone and an ester, they obtained a number of pyridine-substituted β-diketone compounds as fluffy crystals, with varying positions of nitrogen-substitution in the pyridine ring.

Interested? The full story can be read in Chemistry World.

The original article can be read below and is free to access until 9^th June 2017:

Curved fractal structures of pyridine-substituted β-diketone crystals
Zongzheng Qian, Dongxue Li, Tongqing Xie, Xuepeng Zhang,* Yang He, Yuejie Ai and Guoqing Zhang*
CrystEngComm, 2017, 19, 2283-2287
DOI:10.1039/C7CE00462A

The growth and design of organic crystals is often focused on linear regularity and the optical or electronic properties of the resulting crystals.  Crystallisation is influenced by many factors including the presence of interactions between atoms or groups of atoms.  However, when these are absent or insignificant, another kind of morphology can develop – the curved fractal.   A new paper by Zhang et al. looks at the formation of a curved fractal structure and shows an application of these beyond the scientific realm.

Fractals are defined by the existence of the similar patterns occurring independent of the level of detail observed e.g. as seen in Koch snowflakes.  A series of pyridyl diketones, with varying position of ring nitrogen and substitution, and a β-diketone were prepared and their properties compared.

The luminescent 1-(4-methoxyphenyl)-3-(pyridin-2-yl)propane-1,3-dione (PBDK1) showed, uniquely among the structures studied, a curved fractal structure visible using an electron microscope (seen below in fluorescence mode).  The highest curvature was observed for crystals obtained by evaporation from a solution in acetone at 5.0 mg mL⁻¹ or above, on glass.  Under these conditions, the relatively weak (compared with the 3- and 4-pyridyl analogues) potential intermolecular interactions in PBDK1 can be disrupted by surface tension effects.   This allows molecular slippage and dislocation to occur during crystal growth. The observed curved fractal pattern was transferred onto fabric and the design incorporated in a dress which won first place at the 2016 National Women’s Fashion Design Competition of China.

This work suggests some of the factors involved in the formation of curved fractal structures and also shows that interest in these extends beyond the scientific and into the realm of fashion design.

For more information, read the paper at:

Curved fractal structures of pyridine-substituted β-diketone crystals

Zongzheng Qian, Dongxue Li, Tongqing Xie, Xuepeng Zhang, Yang He, Yuejie Ai and Guoqing Zhang

DOI: 10.1039/C7CE00462A

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Gwenda Kyd has a PhD in metallocarborane chemistry from the University of Edinburgh. Other research work includes the spectroscopic study of the structure of glasses and organometallic electron-transfer reactions and the preparation of new inorganic phosphors. She published a book, ‘Molecules, Medicines and Mischief’, in 2014, on some of the chemicals found in plants and is currently working on a follow-up.

A new method of producing vanillin (3-methoxy-4-hydroxybenzaldehyde) from ferulic acid using a catalytic MOP has been reported.

Vanillin, one of the main chemical components of vanilla, is an important flavouring agent in the food, cosmetic and other industries.  However, although it can be extracted from vanilla pods, less than 1% of the required quantity is obtained in this way.  The remainder is obtained by chemical synthesis using strong oxidising agents and toxic solvents.  Biotechnological production is also possible but there are problems with time-scale, purification and the nature of the bacteria used.   There is, therefore, a demand for cleaner, greener methods of production of vanillin.

This paper reports the production of vanillin in 60% yield from ferulic acid and hydrogen peroxide, when a MOP (metal-organic polyhedron) is used as a catalyst.  Like MOFs (metal-organic frameworks), MOPs are constructed from metal ions and organic ligands but rather than forming frameworks, MOPs are discrete polyhedra. MOFs have been widely studied as potential catalysts but MOPs are practically untried.  Reasons for this include their relative lack of stability and tendency to aggregate.   This paper uses the MOP formed from copper(II) and a ligand from 9H-carbazole-3,6-dicarboxylic acid.  There are also coordinated dimethylformamide and water molecules in the structure.

The catalyst is activated by removing the coordinated solvent molecules by heating.  Ferulic acid and hydrogen peroxide are then reacted in the presence of the MOP.  Best results are obtained when the reaction mixture is sonicated (to reduce possible aggregation of MOP molecules).  A mechanism is proposed starting with coordination of peroxide to the active Cu(II) coordination site (schematically shown above).

The recovered catalyst exhibits a loss of crystallinity and after 5 cycles activity shows a decline.  However, the paper demonstrates the potential for the catalytic use of MOPs for the simple production of vanillin and other compounds.

For more details, read the full paper here:

Synthesis of vanillin via a catalytically active Cu(II)-metal organic polyhedron

Gwenda Kyd has a PhD in metallocarborane chemistry from the University of Edinburgh. Other research work includes the spectroscopic study of the structure of glasses and organometallic electron-transfer reactions and the preparation of new inorganic phosphors. She published a book, ‘Molecules, Medicines and Mischief’, in 2014, on some of the chemicals found in plants and is currently working on a follow-up.

Following the success of Peer Review Week in September 2016 (dedicated to reviewer recognition) during which we published a list of our top reviewers, we are delighted to announce that we will continue to recognise the contribution that our reviewers make to the journal by announcing our Outstanding Reviewers each year.

We would like to highlight the Outstanding Reviewers for CrystEngComm in 2016, as selected by the editorial team, for their significant contribution to the journal. The reviewers have been chosen based on the number, timeliness and quality of the reports completed over the last 12 months.

We would like to say a big thank you to those individuals listed here as well as to all of the reviewers that have supported the journal. Each Outstanding Reviewer will receive a certificate to give recognition for their significant contribution.

Professor Dino Aquilano, University of Torino
Dr Timur Atabaev, Seoul National University
Dr Ian Dance, Unversity of New South Wales
Dr Laszlo Fabian, University of East Anglia
Professor Huiging Fan, Northwestern Polytechnical University
Dr Goutam Kole, SRM University
Dr Mahesh Kumar, Indian Institute of Technology Jodhpur
Dr Zheng Ren, University of Connecticut
Dr Dongpeng Yan, Beijing Normal University
Dr Jiatao Zhang, Beijing Institute of Technology

We would also like to thank the CrystEngComm board and the Inorganic community for their continued support of the journal, as authors, reviewers and readers.

If you would like to become a reviewer for our journal, just email us with details of your research interests and an up-to-date CV or résumé.  You can find more details in our author and reviewer resource centre