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ELECTROCHEMICAL METALIZATION CELLS BIG STEP FROM NANOIONICS TO NANOELECTRONICS
Authors: Wágner Tomáš | Kolář Jakub | Valkova Silvie | Voleská Iva | Krbal Miloš | Macák Jan | Frumar Miloslav
Year: 2012
Type of publication: ostatní do riv
Page from-to: nestránkováno
Titles:
Language Name Abstract Keywords
cze ELECTROCHEMICAL METALIZATION CELLS BIG STEP FROM NANOIONICS TO NANOELECTRONICS A range of material systems exist in which nanoscale ionic transport and redox reactions provide the essential for memristive switching. One class relies on mobile cations, which are easily created by electrochemical oxidation of the corresponding electrode metal, transported in the insulating layer, and reduced at the inert counter electrode. These devices are termed electrochemical metallization memories (EMC) or conductive bridge random access memories. The material candidates for electrolytes in such devides have been recently studied. They are amorphous chalcogenides and also oxides (SiO2, WO3, TiO2 and others) containing metal elements (Ag, Cu) or their compounds (Ag2S, CuS) and gaining some portion of ionic conductivity and becoming mixed ionic-electronic conductors. chalkogenidy; nanoelektronika
eng ELECTROCHEMICAL METALIZATION CELLS BIG STEP FROM NANOIONICS TO NANOELECTRONICS A range of material systems exist in which nanoscale ionic transport and redox reactions provide the essential for memristive switching. One class relies on mobile cations, which are easily created by electrochemical oxidation of the corresponding electrode metal, transported in the insulating layer, and reduced at the inert counter electrode. These devices are termed electrochemical metallization memories (EMC) or conductive bridge random access memories. The material candidates for electrolytes in such devides have been recently studied. They are amorphous chalcogenides and also oxides (SiO2, WO3, TiO2 and others) containing metal elements (Ag, Cu) or their compounds (Ag2S, CuS) and gaining some portion of ionic conductivity and becoming mixed ionic-electronic conductors. chalcogenides; electrochemical metallization cell; nanoelectronics