Self-Assembly of Nanovoids in Si Microcrystals Epitaxially Grown on Deeply Patterned Substrates | Zendy

Andrea Barzaghi | Zendy; Saleh Firoozabadi | Zendy; Marco Salvalaglio | Zendy; Roberto Bergamaschini | Zendy; Andrea Ballabio | Zendy; Andreas Beyer | Zendy; Marco Albani | Zendy; J. Valente | Zendy; Axel Voigt | Zendy; Douglas J. Paul | Zendy; Leo Miglio | Zendy; Francesco Montalenti | Zendy; Kerstin Volz | Zendy; Giovanni Isella | Zendy

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Self-Assembly of Nanovoids in Si Microcrystals Epitaxially Grown on Deeply Patterned Substrates

Author(s) -

Andrea Barzaghi,

Saleh Firoozabadi,

Marco Salvalaglio,

Roberto Bergamaschini,

Andrea Ballabio,

Andreas Beyer,

Marco Albani,

J. Valente,

Axel Voigt,

Douglas J. Paul,

Leo Miglio,

Francesco Montalenti,

Kerstin Volz,

Giovanni Isella

Publication year - 2020

Publication title -

crystal growth and design

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 0.966

H-Index - 155

eISSN - 1528-7505

pISSN - 1528-7483

DOI - 10.1021/acs.cgd.9b01312

Subject(s) - nucleation , epitaxy , materials science , nanotechnology , transmission electron microscopy , surface diffusion , semiconductor , substrate (aquarium) , microstructure , fabrication , crystallography , chemical physics , optoelectronics , composite material , chemistry , layer (electronics) , medicine , oceanography , alternative medicine , organic chemistry , adsorption , pathology , geology

We present an experimental and theoretical analysis of the formation of nanovoids within Si microcrystals epitaxially grown on Si patterned substrates. The growth conditions leading to the nucleation of nanovoids have been highlighted, and the roles played by the deposition rate, substrate temperature, and substrate pattern geometry are identified. By combining various scanning and transmission electron microscopy techniques, it has been possible to link the appearance pits of a few hundred nanometer width at the microcrystal surface with the formation of nanovoids within the crystal volume. A phase-field model, including surface diffusion and the flux of incoming material with shadowing effects, reproduces the qualitative features of the nanovoid formation thereby opening new perspectives for the bottom-up fabrication of 3D semiconductors microstructures.

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