Superinsulators: Difference between revisions
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== Superinsulators == | == Superinsulators == | ||
[[Image:Superinsulator.jpeg|thumb|right|Argonne National Laboratory]] | |||
The superinsulating state | A superinsulator is a material that at low temperatures (and possible combinations of other conditions) has a near infinite resistance. The superinsulating state has many parallels to the [[Superconductors|superconducting]] state, and can be destroyed (in a sudden phase transition) by increased temperature, magnetic fields and voltage. | ||
The superinsulating state was first observed on 7 April 2008 by American scientist Valerii Vinokur and Russian scientist Tatyana Baturina at Department of Energy's Argonne National Laboratory in collaboration with several European institutions. It occurred in a titanium nitride film. | |||
This discovery opens new directions of inquiry in condensed matter physics and breaks ground for a new generation of microelectronics. | |||
< | See the article in the March 2010 IEEE Spectrum Magazine, page 11.<br>http://spectrum.ieee.org/semiconductors/materials/scientists-solve-mystery-of-superinsulators | ||
The IEEE has a Society closely aligned [[IEEE Council on SuperConductivity History|here]]. | |||
[[Category:Engineered_materials_&_dielectrics]] | |||
[[Category:Conductivity_&_superconductivity]] | |||
[[Category:Superconducting_devices]] |
Revision as of 19:23, 27 February 2012
Superinsulators
A superinsulator is a material that at low temperatures (and possible combinations of other conditions) has a near infinite resistance. The superinsulating state has many parallels to the superconducting state, and can be destroyed (in a sudden phase transition) by increased temperature, magnetic fields and voltage.
The superinsulating state was first observed on 7 April 2008 by American scientist Valerii Vinokur and Russian scientist Tatyana Baturina at Department of Energy's Argonne National Laboratory in collaboration with several European institutions. It occurred in a titanium nitride film.
This discovery opens new directions of inquiry in condensed matter physics and breaks ground for a new generation of microelectronics.
See the article in the March 2010 IEEE Spectrum Magazine, page 11.
http://spectrum.ieee.org/semiconductors/materials/scientists-solve-mystery-of-superinsulators
The IEEE has a Society closely aligned here.