Technology of Synthesis of Opal Matrix Metamaterials

Alexander Bagdasarian; Mikhail Samoylovich; Alpik Mkrtchyan; Anatoly Rinkevich; Alexey Belyanin; Sergey Bagdasarian; Artak Mkrtchyan; Anastasia Afanasieva

doi:10.4028/www.scientific.net/AMR.1084.58

Paper Titles

Laws of Radiation Grafting of Styrene to PVDF Films and Characterization of the Grafted Polymer
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Methods of Uranium Hexafluoride Purification
p.46

Obtaining Hydrogen and Carbon Materials from Hydrocarbonic Gas in Microwave Plasma Discharge at Amospheric Pressure
p.50

Study on the Spatial Structure of Ultrafine-Grained Light Alloys by Microtomography
p.54

Technology of Synthesis of Opal Matrix Metamaterials
p.58

Temperature Effect on the Rate of Hydrogen Desorption by Carbon Materials
p.61

UHF-Properties of Nanocomposites: Magnetic Resonance
p.66

Simulation of the Uranium Crystallization Process Using Cellular Automata
p.72

Development of a Thermal Model of the Experimental Electrolyzer
p.77

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1084Technology of Synthesis of Opal Matrix...

Technology of Synthesis of Opal Matrix Metamaterials

Abstract:

This work describes the technology of growing crystal metamaterials spinel ferrites. Metamaterials is one of the most promising classes of materials for use in optical devices in the microwave range and features, which can be used for creation of controlled attenuators, phase shifters, and other devices.

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Periodical:

Advanced Materials Research (Volume 1084)

Pages:

58-60

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1084.58

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Online since:

January 2015

Authors:

Alexander Bagdasarian, Mikhail Samoylovich, Alpik Mkrtchyan*, Anatoly Rinkevich, Alexey Belyanin, Sergey Bagdasarian, Artak Mkrtchyan, Anastasia Afanasieva

Keywords:

Metamaterials, Opal Matrices, Spinel Ferrites, Technology

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* - Corresponding Author

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