Active metal template synthesis of rotaxanes, catenanes and molecular shuttles
Active metal template synthesis of rotaxanes, catenanes and molecular shuttles
Active metal template synthesis is a powerful new strategy for the construction of rotaxanes, catenanes and other mechanically interlocked molecular structures. The key feature is that the metal plays a dual role during the assembly of the interlocked architecture, acting as both a template for entwining or threading the components and as a catalyst for capturing the interlocked final product by covalent bond formation. Unlike traditional “passive” metal template methods to rotaxanes and catenanes, permanent recognition motifs are not required on each of the components to be interlocked (i.e., the assembly can be traceless) and the template can often be used in sub-stoichiometric quantities. Since its inception in 2006, a rapidly growing number of different metal-catalysed reactions have proven suitable for the active metal template synthesis of both rotaxanes and catenanes, including the copper(I)-catalysed terminal alkyne–azide cycloaddition (the CuAAC “click” reaction), palladium- and copper-catalysed alkyne homocouplings and heterocouplings, and palladium-catalysed oxidative Heck couplings and Michael additions. In addition to simple rotaxanes and catenanes, the synthetic strategy has been used to construct switchable molecular shuttles with weak intercomponent interactions (a requirement for fast shuttling) and to provide insight into the mechanisms of transition metal-catalysed reactions. In this tutorial review we highlight the utility and potential of the early examples of the active metal template strategy in mechanically interlocked molecule synthesis.
1530-1541
Crowley, James D.
2d5e4e7f-b835-496a-a7db-e1a1856226db
Goldup, Stephen M.
0a93eedd-98bb-42c1-a963-e2815665e937
Lee, Ai-Lan
df4cd6d7-08ae-498d-b9e7-26e3449155d3
Leigh, David A.
826353b6-267f-44cd-a7e7-adf0c34f66c9
McBurney, Roy T.
200683de-6158-4a21-8d22-68adc26f0e59
16 April 2009
Crowley, James D.
2d5e4e7f-b835-496a-a7db-e1a1856226db
Goldup, Stephen M.
0a93eedd-98bb-42c1-a963-e2815665e937
Lee, Ai-Lan
df4cd6d7-08ae-498d-b9e7-26e3449155d3
Leigh, David A.
826353b6-267f-44cd-a7e7-adf0c34f66c9
McBurney, Roy T.
200683de-6158-4a21-8d22-68adc26f0e59
Crowley, James D., Goldup, Stephen M., Lee, Ai-Lan, Leigh, David A. and McBurney, Roy T.
(2009)
Active metal template synthesis of rotaxanes, catenanes and molecular shuttles.
Chemical Society Reviews, 38 (6), .
(doi:10.1039/b804243h).
(PMID:19587949)
Abstract
Active metal template synthesis is a powerful new strategy for the construction of rotaxanes, catenanes and other mechanically interlocked molecular structures. The key feature is that the metal plays a dual role during the assembly of the interlocked architecture, acting as both a template for entwining or threading the components and as a catalyst for capturing the interlocked final product by covalent bond formation. Unlike traditional “passive” metal template methods to rotaxanes and catenanes, permanent recognition motifs are not required on each of the components to be interlocked (i.e., the assembly can be traceless) and the template can often be used in sub-stoichiometric quantities. Since its inception in 2006, a rapidly growing number of different metal-catalysed reactions have proven suitable for the active metal template synthesis of both rotaxanes and catenanes, including the copper(I)-catalysed terminal alkyne–azide cycloaddition (the CuAAC “click” reaction), palladium- and copper-catalysed alkyne homocouplings and heterocouplings, and palladium-catalysed oxidative Heck couplings and Michael additions. In addition to simple rotaxanes and catenanes, the synthetic strategy has been used to construct switchable molecular shuttles with weak intercomponent interactions (a requirement for fast shuttling) and to provide insight into the mechanisms of transition metal-catalysed reactions. In this tutorial review we highlight the utility and potential of the early examples of the active metal template strategy in mechanically interlocked molecule synthesis.
This record has no associated files available for download.
More information
Published date: 16 April 2009
Organisations:
Organic Chemistry: Synthesis, Catalysis and Flow
Identifiers
Local EPrints ID: 370662
URI: http://eprints.soton.ac.uk/id/eprint/370662
ISSN: 0306-0012
PURE UUID: f623902d-0cdf-4678-9f1d-67c6e1f53574
Catalogue record
Date deposited: 03 Nov 2014 13:48
Last modified: 14 Mar 2024 18:20
Export record
Altmetrics
Contributors
Author:
James D. Crowley
Author:
Ai-Lan Lee
Author:
David A. Leigh
Author:
Roy T. McBurney
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
