Effect of nanoscale surface roughness on the bonding energy of direct-bonded silicon wafers
Effect of nanoscale surface roughness on the bonding energy of direct-bonded silicon wafers
Direct wafer bonding of silicon wafers is a promising technology for manufacturing three-dimensional complex microelectromechanical systems as well as silicon-on-insulator substrates. Previous work has reported that the bond quality declines with increasing surface roughness, however, this relationship has not been quantified. This article explicitly correlates the bond quality, which is quantified by the apparent bonding energy, and the surface morphology via the bearing ratio, which describes the area of surface lying above a given depth. The apparent bonding energy is considered to be proportional to the real area of contact. The effective area of contact is defined as the area sufficiently close to contribute to the attractive force between the two bonding wafers. Experiments were conducted with silicon wafers whose surfaces were roughened by a buffered oxide etch solution (BOE, HF:NH4F = 1:7) and/or a potassium hydroxide solution. The surface roughness was measured by atomic force microscopy. The wafers were direct bonded to polished "monitor" wafers following a standard RCA cleaning and the resulting bonding energy was measured by the crack-opening method. The experimental results revealed a clear correlation between the bonding energy and the bearing ratio. A bearing depth of ~1.4 nm was found to be appropriate for the characterization of direct-bonded silicon at room temperature, which is consistent with the thickness of the water layer at the interface responsible for the hydrogen bonds that link the mating wafers.
6800-6806
Miki, N.
63e62cce-98a6-4951-a772-30a1152affa0
Spearing, S.M.
9e56a7b3-e0e8-47b1-a6b4-db676ed3c17a
2003
Miki, N.
63e62cce-98a6-4951-a772-30a1152affa0
Spearing, S.M.
9e56a7b3-e0e8-47b1-a6b4-db676ed3c17a
Miki, N. and Spearing, S.M.
(2003)
Effect of nanoscale surface roughness on the bonding energy of direct-bonded silicon wafers.
Journal of Applied Physics, 94 (10), .
(doi:10.1063/1.1621086).
Abstract
Direct wafer bonding of silicon wafers is a promising technology for manufacturing three-dimensional complex microelectromechanical systems as well as silicon-on-insulator substrates. Previous work has reported that the bond quality declines with increasing surface roughness, however, this relationship has not been quantified. This article explicitly correlates the bond quality, which is quantified by the apparent bonding energy, and the surface morphology via the bearing ratio, which describes the area of surface lying above a given depth. The apparent bonding energy is considered to be proportional to the real area of contact. The effective area of contact is defined as the area sufficiently close to contribute to the attractive force between the two bonding wafers. Experiments were conducted with silicon wafers whose surfaces were roughened by a buffered oxide etch solution (BOE, HF:NH4F = 1:7) and/or a potassium hydroxide solution. The surface roughness was measured by atomic force microscopy. The wafers were direct bonded to polished "monitor" wafers following a standard RCA cleaning and the resulting bonding energy was measured by the crack-opening method. The experimental results revealed a clear correlation between the bonding energy and the bearing ratio. A bearing depth of ~1.4 nm was found to be appropriate for the characterization of direct-bonded silicon at room temperature, which is consistent with the thickness of the water layer at the interface responsible for the hydrogen bonds that link the mating wafers.
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Published date: 2003
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Local EPrints ID: 22782
URI: http://eprints.soton.ac.uk/id/eprint/22782
ISSN: 0021-8979
PURE UUID: b218e740-58a4-460a-ba5b-da82c32c65f3
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Date deposited: 10 Mar 2006
Last modified: 16 Mar 2024 03:37
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N. Miki
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