@inproceedings{e128d60cf34f44029828aa1ff356e6c8,
title = "Low-Temperature Rough-Surface Wafer Bonding with AlN/AlN Via Oxygen Plasma Activation",
abstract = "We demonstrate breaking through the main obstacle to achieve perfect wafer bonding: the requirement of the surface needs to be very flat and smooth. Strictly, the roughness must be less than 0.5 {\AA}. We use sintered aluminum nitride as an example. AlN is a ceramic material with excellent dielectric and thermal properties and is usually used in the fields of microelectronics and energy. Despite CMP polishing, the high roughness (rms> 10 nm) of AlN wafers due to voids formed in sintering cannot meet the surface requirements for direct wafer bonding (rms < 5 {\AA}). We present that bonding an AlN to another AlN with a high roughness surface can be achieved by design bonding processing. First, we used oxygen plasma to activate the hydrophobic rough surface to become a hydrophilic surface to introduce strong capillary action. Then, both surfaces of the bonded AlN/AlN pair were reacted with bonding species (OH-). The reaction was strengthened via electron transfer caused by clamping the bonded AlN/Al pair. Finally, low-temperature annealing (<150°C) was performed on the bonded AlN/AlN pair to synthesize Al2O3 at the bonding interface. After annealing at 150°C for 4 hours, the bonding interface of the AlN bonding pair was observed with scanning electron microscopy (SEM), as shown in Figure 1. There is a transition layer between the bonding surfaces, in which the nitrogen concentration decreases and the oxygen concentration increases significantly. Alumina layer is formed by hydrolysis and dehydration, which acts as a bridge to firmly connect the two AlN wafers.",
author = "Huang, {Wei Chi} and Nien, {Shao Ming} and Ruan, {Jian Long} and Kuo, {Yang Kuao} and Lee, {Benjamin T.H.}",
note = "Publisher Copyright: {\textcopyright} 2022 ECS - The Electrochemical Society.; 241st ECST Meeting ; Conference date: 29-05-2022 Through 02-06-2022",
year = "2022",
doi = "10.1149/10801.0049ecst",
language = "???core.languages.en_GB???",
series = "ECS Transactions",
publisher = "Institute of Physics",
number = "1",
pages = "49--50",
booktitle = "ECS Transactions",
edition = "1",
}