Peer-Reviewed Journal Details
Mandatory Fields
Hendon, CH;Tiana, D;Walsh, A
2012
January
Physical Chemistry Chemical Physics
Conductive metal-organic frameworks and networks: fact or fantasy?
Validated
Optional Fields
FIELD-EFFECT TRANSISTORS THIN-FILM TRANSISTORS DIMENSIONAL COORDINATION POLYMERS RADICAL-ANION SALT CRYSTAL-STRUCTURE N-CHANNEL HYBRID SEMICONDUCTORS OPTICAL-PROPERTIES CHARGE-TRANSPORT TRIFLUOROMETHYLPHENYL GROUPS
14
13120
13132
Electrical conduction is well understood in materials formed from inorganic or organic building blocks, but their combination to produce conductive hybrid frameworks and networks is an emerging and rapidly developing field of research. Self-assembling organic-inorganic compounds offer immense potential for functionalising material properties for a wide scope of applications including solar cells, light emitters, gas sensors and bipolar transparent conductors. The flexibility of combining two distinct material classes into a single solid-state system provides an almost infinite number of chemical and structural possibilities; however, there is currently no systematic approach established for designing new compositions and configurations with targeted electronic or optical properties. We review the current status in the field, in particular, the range of hybrid systems reported to date and the important role of materials modelling in the field. From theoretical arguments, the Mott insulator-to-metal transition should be possible in semiconducting metal-organic frameworks, but has yet to be observed. The question remains as to whether electro-active hybrid materials will evolve from chemical curiosities towards practical applications in the near term.
CAMBRIDGE
1463-9076
10.1039/c2cp41099k
Grant Details