Metal doping of dielectric thin layers by electric field assisted film dissolution

•Dielectric thin film metal doping performed by electric field assisted dissolution.•Numerical modelling reveals dopant ion distribution time evolution.•Doping values and time-scale are correlated with material parameters.•Doping evolution in Ag/SiO2/glass can be optically tracked by ellipsometry. T...

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Bibliographic Details
Published in:Journal of non-crystalline solids 2021-02, Vol.554, p.120584, Article 120584
Main Authors: Okorn, Boris, Sancho-Parramon, Jordi, Oljaca, Miodrag, Janicki, Vesna
Format: Article
Language:English
Subjects:
Electric field assisted dissolution
Ellipsometry
Glass poling
Metal doping
Refractive index
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Summary:•Dielectric thin film metal doping performed by electric field assisted dissolution.•Numerical modelling reveals dopant ion distribution time evolution.•Doping values and time-scale are correlated with material parameters.•Doping evolution in Ag/SiO2/glass can be optically tracked by ellipsometry. The incorporation of metal ions in dielectric layers by means of electric field assisted film dissolution is investigated. The samples consist of alkali-containing glass substrates coated first with SiO2 and then Ag thin films. The application of moderately elevated temperatures and DC voltages induces thermal poling in the glass matrix and metal film dissolution, resulting in the incorporation of metal ions in both dielectric layer and glass matrix. First, the process dynamics are simulated by modelling the migration of metal film ions and alkali species under an applied electric field. Numerical solution of the model indicates that metal ions progressively dope the dielectric layer until they reach the glass matrix. Then the dopant distribution in the layer becomes steady-state and further injection of ions contributes to increase the dopant concentration in glass. The influence on the process of alkali and dopant ion mobilities and alkali ion concentration is analysed. Additionally, Ag doping of SiO2 layers deposited on soda-lime and borosilicate glasses is experimentally carried out and characterized using spectroscopic ellipsometry. The evolution of refractive index profiles through both, SiO2 layer and glass substrate, is correlated with ion migration and confirms the model trends. Overall, this study shows that glass poling and film dissolution can be used to control metal doping of dielectric layers, with potential application in optical and photonic devices.
ISSN:0022-3093
1873-4812
DOI:10.1016/j.jnoncrysol.2020.120584