Modular nanometer-scale structuring of gel fibres by sequential self-organization

Applegarth, L.; Clark, N.; Richardson, A.C.; Parker, A.D.M.; Radosavljevic-Evans, I.; Goeta, A.E.; Howard, J.A.K.; Steed, J.W.

Modular nanometer-scale structuring of gel fibres by sequential self-organization

Applegarth, L.; Clark, N.; Richardson, A.C.; Parker, A.D.M.; Radosavljevic-Evans, I.; Goeta, A.E.; Howard, J.A.K.; Steed, J.W.

Authors

L. Applegarth

N. Clark

A.C. Richardson

A.D.M. Parker

I. Radosavljevic-Evans

A.E. Goeta

Judith Howard j.a.k.howard@durham.ac.uk
Emeritus Professor

Professor Jonathan Steed jon.steed@durham.ac.uk
Professor

Contributors

Professor Ivana Evans ivana.radosavljevic@durham.ac.uk
Other

Abstract

Ag(I) and Cu(II) complexes of a series of simple bis( urea) ligands form soft metallogels. X-ray crystallographic results suggests that the gels' structure is based on hydrogen bonding to counter anions and thus suggests a route to tunable gel rheological properties.

Citation

Applegarth, L., Clark, N., Richardson, A., Parker, A., Radosavljevic-Evans, I., Goeta, A., Howard, J., & Steed, J. (online). Modular nanometer-scale structuring of gel fibres by sequential self-organization. Chemical Communications, 5423-5425

Journal Article Type	Article
Journal	Chemical Communications
Print ISSN	1359-7345
Electronic ISSN	1364-548X
Publisher	Royal Society of Chemistry
Peer Reviewed	Peer Reviewed
Issue	43
Pages	5423-5425
Public URL	https://durham-repository.worktribe.com/output/1603811