Dielectric properties and reliability enhancement of atomic layer deposited thin films by: In situ atomic layer substrate biasing
Journal
Journal of Materials Chemistry C
Journal Volume
8
Journal Issue
37
Pages
13025-13032
Date Issued
2020
Author(s)
Chou, C.-Y.
Chang, T.-J.
Wang, C.-I.
Wang, C.-Y.
Yin, Y.-T.
Chung, T.-F.
Yang, J.-R.
Lin, H.-C.
Chen, M.-J.
Abstract
A novel "atomic layer substrate biasing (ALSB)"technique is proposed to improve the dielectric properties including film density, dielectric constant (K), and leakage current density (Jg) and the reliability of nanoscale thin films. In the ALSB process, in situ Ar plasma generated by substrate biasing is layer-by-layer introduced into each cycle of atomic layer deposition. Energy delivery from the plasma toward the as-deposited layer boosts the migration of adatoms, leading to ∼10% increase of the film density, ∼3-order-of-magnitude reduction of Jg, and an increment of K being as large as 40.7 of a ZrO2 layer of ∼5 nm. The reliability enhancement upon the ALSB treatment is demonstrated by constant-voltage-stress (CVS) and the time-dependent-dielectric-breakdown (TDDB) tests, which confirm the suppression of stress-induced traps and a high electric field of 4.7 MV cm-1 projected for a 10 year lifetime. Significant improvements in the film density, Jg, K, and the reliability indicate that ALSB is a highly effective technique to modify the quality of ALD-deposited thin films, which can be widely used in a variety of fields including energy saving, green energy, nanoelectronics, and biomedical applications. This journal is © 2020 The Royal Society of Chemistry.
SDGs
Other Subjects
Atoms; Dielectric materials; Dielectric properties of solids; Electric breakdown; Energy conservation; Leakage currents; Medical applications; Reliability; Thin films; Zirconia; Atomic layer deposited; Atomic-layer substrates; Biomedical applications; Constant voltage stress; Dielectric constants (k); Nanoscale thin films; Reliability enhancement; Time dependent dielectric breakdown; Atomic layer deposition
Type
journal article