Author
Listed:
- Kyle L. Morris
(School of Life Sciences, Chichester II Building, University of Sussex)
- Lin Chen
(University of Liverpool)
- Jaclyn Raeburn
(University of Liverpool)
- Owen R. Sellick
(School of Chemistry, Main building, Cardiff University)
- Pepa Cotanda
(University of Warwick)
- Alison Paul
(School of Chemistry, Main building, Cardiff University)
- Peter C. Griffiths
(School of Science, University of Greenwich)
- Stephen M. King
(Rutherford Appleton Laboratory, Science and Technology Facilities Council)
- Rachel K. O’Reilly
(University of Warwick)
- Louise C. Serpell
(School of Life Sciences, Chichester II Building, University of Sussex)
- Dave J. Adams
(University of Liverpool)
Abstract
Controlling the order and spatial distribution of self-assembly in multicomponent supramolecular systems could underpin exciting new functional materials, but it is extremely challenging. When a solution of different components self-assembles, the molecules can either coassemble, or self-sort, where a preference for like-like intermolecular interactions results in coexisting, homomolecular assemblies. A challenge is to produce generic and controlled ‘one-pot’ fabrication methods to form separate ordered assemblies from ‘cocktails’ of two or more self-assembling species, which might have relatively similar molecular structures and chemistry. Self-sorting in supramolecular gel phases is hence rare. Here we report the first example of the pH-controlled self-sorting of gelators to form self-assembled networks in water. Uniquely, the order of assembly can be predefined. The assembly of each component is preprogrammed by the pKa of the gelator. This pH-programming method will enable higher level, complex structures to be formed that cannot be accessed by simple thermal gelation.
Suggested Citation
Kyle L. Morris & Lin Chen & Jaclyn Raeburn & Owen R. Sellick & Pepa Cotanda & Alison Paul & Peter C. Griffiths & Stephen M. King & Rachel K. O’Reilly & Louise C. Serpell & Dave J. Adams, 2013.
"Chemically programmed self-sorting of gelator networks,"
Nature Communications, Nature, vol. 4(1), pages 1-6, June.
Handle:
RePEc:nat:natcom:v:4:y:2013:i:1:d:10.1038_ncomms2499
DOI: 10.1038/ncomms2499
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