电邮这篇文章 Hybrid Organosilicate Low-k Dielectrics with Benzene Bridge Groups with Increased Mechanical Properties and Small Pore Size for Modern BEOL Metallization
- 作者: Rezvanov A.A.1, Vishnevskiy A.S.2, Seregin D.S.2, Lomov A.A.3, Vorotilov K.A.2, Baklanov M.R.2
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隶属关系:
- MERI
- MIREA – Russian Technological University
- Valiev Institute of Physics and Technology, RAS
- 期: 卷 118, 编号 2 (2023): THEMED SECTION: FUNDAMENTAL PROBLEMS OF MULTILEVEL METALLIZATION SYSTEMS FOR ULTRA-LARGE INTEGRATED CIRCUITS
- 页面: 13-30
- 栏目: THEMED SECTION: FUNDAMENTAL SCIENTIFIC RESEARCH IN THE FIELD OF NATURAL SCIENCES
- URL: https://ogarev-online.ru/1605-8070/article/view/301041
- DOI: https://doi.org/10.22204/2410-4639-2023-118-02-13-30
- ID: 301041
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全文:
详细
In this work, the critical properties of a periodic mesoporous organosilicate dielectric with different ratios of benzene bridging and methyl groups are studied using various modern methods, such as ellipsometric porosimetry, surface acoustic wave spectroscopy, X-ray reflectometry, and others. It is shown that the pore size and surface roughness of the films decrease with an increase in the concentration of benzene groups, although at a concentration of >25 mol.%, the pore size sharply decreases and changes little with a further increase. With an increase in the concentration of benzene groups, the dielectric constant also increases and the mechanical properties improve. The increase in Young's modulus has a percolate behavior and increases sharply at a concentration close to 50 mol.%. It was found that the introduction of 30 wt.% porosity in films with benzene groups, in which there are no methyl groups, leads to an increase in Young's modulus. This behavior is associated with the formation of a crystal-like structure on the film framework. An increase in the dielectric constant is associated with the greater polarizability of benzene groups compared to methyl groups, as well as with their greater hydrophilicity and the presence of adsorbed water.
作者简介
Askar Rezvanov
MERI
编辑信件的主要联系方式.
Email: arezvanov@niime.ru
俄罗斯联邦, 6/1 Akademika Valieva Str., Moscow, Zelenograd, 124460, Russia
Alexey Vishnevskiy
MIREA – Russian Technological University
Email: vishnevskiy@mirea.ru
俄罗斯联邦, 78 Vernadsky Ave., Moscow, 119454, Russia
Dmitry Seregin
MIREA – Russian Technological University
Email: d_seregin@mirea.ru
俄罗斯联邦, 78 Vernadsky Ave., Moscow, 119454, Russia
Andrey Lomov
Valiev Institute of Physics and Technology, RAS
Email: lomov@ftian.ru
俄罗斯联邦, 36/1 Nakhimovsky Ave., Moscow, 117218, Russia
Konstantin Vorotilov
MIREA – Russian Technological University
Email: vorotilov@mirea.ru
俄罗斯联邦, 78 Vernadsky Ave., Moscow, 119454, Russia
Mikhail Baklanov
MIREA – Russian Technological University
Email: baklanovmr@gmail.com
俄罗斯联邦, 78 Vernadsky Ave., Moscow, 119454, Russia
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