AlAl thermocompression bonding for wafer-level MEMS sealing

Malik, Nishant; Schjølberg-Henriksen, Kari; Poppe, Erik; Finstad, T. G.

doi:10.1016/j.sna.2014.02.030

Cited by 52 publications

(27 citation statements)

References 8 publications

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“…Similar temperature and pressure dependences are observed when Sn layers are placed on Al surface and between Al layers; therefore, as long as Sn exists inside Al, high‐yield long‐standing vacuum sealing is achieved in Al‐Al bonding at 400 °C and lower, even though Al surface has been exposed to atmosphere. On the other hand, when no Sn exists in bonding layer, vacuum sealing cannot be achieved in Al‐Al bonding below 400 °C, which agrees with previous reports on conventional Al‐Al bonding .…”

Section: Resultssupporting

confidence: 90%

“…(2) as can be seen from Al-Sn binary phase diagram in Fig. 3 [7], eutectic reaction in Al-Sn system occurs at Sn concentration of 97.6 at% and temperature of 228°C, and no intermetallic compounds exist in entire phase space, so that Al parts can easily come into contact with each other via liquid phase with near-liquidus composition in thermocompression bonding process, and Al interdiffusion can be expected on the contact surface; (3) oxidation rate of Sn in atmosphere at room temperature is slow, and the thickness of oxide film is below 10 nm after 100 h [8]; (4) and Sn vapor pressure at 400°C is as low as about 10 −12 Pa [9], and has no effect on vacuum sealing. The reason behind choosing Mg as an additive element is that when 0.3 wt% Mg to 5 wt% Mg is added in high vacuum bonding of Al at 450°C and higher, products of reaction between Al 2 O 3 and Mg are formed and coagulate; this results in destruction of the surface oxide film so that exposed Al area expands, thus contributing to a firm bonding.…”

Section: Experimental Methodsmentioning

confidence: 99%

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Role of Thin Sn Layer for Low Temperature Al‐Al Thermo‐compression Bonding of Wafer‐Level Hermetic Sealing

Satoh

Fukushi

Esashi

et al. 2018

Elect Comm in Japan

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SUMMARY This paper reports low temperature hermetic wafer bonding using Al/Sn/Al/Sn/Al as a bonding layer. The Al surface of the bonding layer was oxidized in air, but hermetic sealing was demonstrated without surface treatment at 370 °C to 390 °C, which was lower than the maximum temperature of complementary metal oxide semiconductor (CMOS) backend process (400 °C). For the successfully sealed samples, the bonding layer was considerably compressed and squeezed, and the remaining thickness was only <16% of the initial one, that is, the reduction rate was >84%. On the other hand, the samples without Sn layers inserted, that is, using a pure Al bonding layer, were not hermetically sealed at similar temperatures, showing the reduction rate smaller than 70%. A clear correlation between the reduction rate and the yield of hermetic sealing was observed. Taking account of analytical results and Al‐Sn phase diagram, it is suggested that Al‐Sn liquid phase in Al grain boundaries enhances the grain slip deformation of the bonding layer and fractionates the surface Al oxide layer during the bonding process. The function of Sn for Al‐Al bonding suggested in this paper is useful for wafer‐level hermetic micro electro mechanical systems (MEMS) packaging at low temperature.

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Section: Resultssupporting

confidence: 90%

Section: Experimental Methodsmentioning

confidence: 99%

Role of Thin Sn Layer for Low Temperature Al‐Al Thermo‐compression Bonding of Wafer‐Level Hermetic Sealing

Satoh

Fukushi

Esashi

et al. 2018

Elect Comm in Japan

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“…[17][18][19] It was found that Al films sputtered on SiO2 can be bonded at lower temperatures than those sputtered directly on Si wafers. 18 We also found that higher quality bonding in terms of dicing yield and bond strength can be achieved by increasing the bonding temperature and/or bond force.…”

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confidence: 99%

“…18 We also found that higher quality bonding in terms of dicing yield and bond strength can be achieved by increasing the bonding temperature and/or bond force. 17 In the current work, we use transmission electron microscopy (TEM) to investigate bonded interfaces realized with Al deposited on Si or on SiO2 to explore possible reasons leading to differences in dicing yield. The impact of increasing the bond force and bond temperature on the resulting bond interface is also investigated.…”

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confidence: 99%

Interfacial characterization of Al-Al thermocompression bonds

Malik

Carvalho

Poppe

et al. 2016

Journal of Applied Physics

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Interfaces formed by Al-Al thermocompression bonding were studied by transmission electron microscopy. Si wafer pairs were bonded using Al films deposited on Si or SiO2 as intermediate bonding media. A bond force of 36 or 60 kN at bonding temperatures ranging from 400-550 °C was applied for a duration of 60 min. Differences in bonded interfaces of 200 µm wide sealing frames were investigated. Interface having voids was observed for bonding with 36 kN at 400 °C for Al deposited both on Si and on SiO2. However, the dicing yield was 33 % for Al on Si and 98 % for Al on SiO2, attesting for the higher quality of the latter bonds. Both a bond force of 60 kN applied at 400 °C and a bond force of 36 kN applied at 550 °C resulted in completely bonded frames with dicing yields of, respectively, 100 and 96 %. A high density of long dislocations in the Al grains was observed for the 60 kN case, while the higher temperature resulted in grain boundary rotation away from the original Al-Al interface towards more stable configurations.Possible bonding mechanisms and reasons for the large difference in bonding quality of the Al films deposited on Si or SiO2 are discussed.3

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“…As a calculation shows (4), the elastic energy is too low to influence the bonding between atoms directly, but the applied stress and the resulting strain breaks up the surface layer. The wafers are bonded at high temperatures, usually in the range of 400°C to 550°C (1)(2)(3)(5)(6)(7). In recent experiments, Malik et al were able to reduce the required bonding temperature to about 300°C by depositing the Al metallization layer onto an intermediate SiO2 layer (3).…”

Section: Introductionmentioning

confidence: 99%

Low-Temperature Aluminum-Aluminum Wafer Bonding

et al. 2016

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Aluminum-aluminum thermo-compression wafer bonding is becoming increasingly important in the production of microelectromechanical systems (MEMS) devices. As the chemically highly stable aluminum oxide layer acts as a diffusion barrier between the two aluminum metallization layers, up to now the process has required bonding temperatures of 300°C or more. By using the EVG®580 ComBond® system, in which a surface treatment and subsequent wafer bonding are both performed in a high vacuum cluster, for the first time successful Al-Al wafer bonding was possible at a temperature of 100°C. The bonded interfaces of blank Al wafers and Al wafers with patterned frames were characterized using C-mode scanning acoustic microscopy (C-SAM) and transmission electron microscopy (TEM) as well as dicing yield and pull tests representative for the bonding strength. The investigations revealed areas of oxide-free, atomic contact at the Al-Al bonded interface.

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AlAl thermocompression bonding for wafer-level MEMS sealing

Cited by 52 publications

References 8 publications

Role of Thin Sn Layer for Low Temperature Al‐Al Thermo‐compression Bonding of Wafer‐Level Hermetic Sealing

Role of Thin Sn Layer for Low Temperature Al‐Al Thermo‐compression Bonding of Wafer‐Level Hermetic Sealing

Interfacial characterization of Al-Al thermocompression bonds

Low-Temperature Aluminum-Aluminum Wafer Bonding

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