Reliability Assessment of Thermocompressed Epoxy Molding Compound through Glass via Interposer Architecture by the Submodeling Simulation Approach

Wang, Shih-Hung; Hsu, Wensyang; Liou, Yan-Yu; Huang, Pei‐Chen; Lee, Chang‐Chun

doi:10.3390/ma15207357

Cited by 6 publications

(9 citation statements)

References 34 publications

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“…The glass interposer architecture utilized in this study comprises a 100 mm ×100 mm interposer and array-type Cu-filled TGV with a via diameter of 28 μm and a TGV pitch of 1 mm. Multi-chiplet arrangement design is further attached on the glass interposer, unlike the original vehicle utilized in the previous study [ 40 ]. As shown in Figure 7 , a one-quarter FEA model of an entire glass interposer vehicle is built in accordance with the symmetry of structure design.…”

Section: Utilizing the Equivalent Materials Approach And Submodeling ...mentioning

confidence: 99%

“…The considered structural layout parameters of TGV, namely via diameter and via pitch, are defined as 28 µm and 1 mm, respectively, for the baseline design. The detailed fabrication process was demonstrated in the previous study [40]. The process steps are described Micromachines 2023, 14, 1506 4 of 15 as follows.…”

Section: Structural Layout Design and Fabrication Process Of The Cu-f...mentioning

confidence: 99%

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Layout Dependence Stress Investigation in through Glass via Interposer Architecture Using a Submodeling Simulation Technique and a Factorial Design Approach

et al. 2023

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The multi-chiplet technique is expected to be a promising solution to achieve high-density system integration with low power consumption and high usage ratio. This technique can be integrated with a glass interposer to accomplish a competitive low fabrication cost compared with the silicon-based interposer architecture. In this study, process-oriented stress simulation is performed by the element activation and deactivation technique in finite element analysis architecture. The submodeling technique is also utilized to mostly conquer the scale mismatch and difficulty in mesh gridding design. It is also used to analyze the thermomechanical responses of glass interposers with chiplet arrangements and capped epoxy molding compounds (EMC) during curing. A three-factor, three-level full factorial design is applied using the analysis of variance method to explore the significance of various structural design parameters for stress generation. Analytic results reveal that the maximum first principal stresses of 130.75 and 17.18 MPa are introduced on the sidewall of Cu-filled via and the bottom of the glass interposer, respectively. Moreover, the EMC thickness and through glass via pitch are the dominant factors in the adopted vehicle. They significantly influence the stress magnitude during heating and cooling.

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Section: Utilizing the Equivalent Materials Approach And Submodeling ...mentioning

confidence: 99%

Section: Structural Layout Design and Fabrication Process Of The Cu-f...mentioning

confidence: 99%

Layout Dependence Stress Investigation in through Glass via Interposer Architecture Using a Submodeling Simulation Technique and a Factorial Design Approach

et al. 2023

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“…Silva properties of molds required when performing molding processes using special materials, such as carbon fiber, epoxy, biodegradable components, and titanium alloys, and use them to optimize the molding process. [12][13][14][15] However, very few studies have attempted a scientific approach to minimize flash, which is a major problem in the tip-forming process, which is essential for catheter manufacturing.…”

Section: Introductionmentioning

confidence: 99%

“…Silva et al and Kanbur et al conducted a study to improve molding performance by optimizing the cooling channel in the mold, 9,10 and Kuo et al conducted a study to analyze the molding characteristics by changing the cooling channel as well as the cooling process and consider the productivity in injection molding 11 . In addition, Kipping et al, Major‐Gabryś et al, Wang et al, and Waalkes et al performed research to analyze the material, heat transfer, and rheological properties of molds required when performing molding processes using special materials, such as carbon fiber, epoxy, biodegradable components, and titanium alloys, and use them to optimize the molding process 12–15 . However, very few studies have attempted a scientific approach to minimize flash, which is a major problem in the tip‐forming process, which is essential for catheter manufacturing.…”

Section: Introductionmentioning

confidence: 99%

Improvement of catheter tip morphology by mold material used for tip‐forming process

Lee

Wei

Lee

et al. 2023

Polymer Engineering & Sci

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As interventional procedures using catheters have rapidly developed, accordingly, the incidence of polymeric embolization is also increasing, with the main cause being the flash generated during tip forming of the catheter. This study has performed to change the material of the mold used to form catheter tips to prevent flash, which is a cause of polymeric embolism. The tip‐forming performance and the flash generation according to the main parameters of the tip‐forming process were analyzed: power, heating, cooling time, and insertion pressure. In addition, we observed the effect of flash suppression according to temperature sensitivity by changing the mold material considering thermal conductivity and electrical resistivity. In particular, considering the glass transition temperature of HDPE (high‐density polyethylene), which is applied to sheath and dilator catheters, the most stable tip forming proceeds when the temperature near the tip inside the mold was about 130°C. We verified experimentally and numerically that the temperature of the pins comprising the mold plays an important role in flash generation and confirmed that the viscosity of the polymer melts is lower at 120°C than at 90°C of the pin, and flash is minimized because of the shear‐thinning behavior of the polymer melts.

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“…Figure 2 shows a schematic diagram of the structure during the decarrier process, where "Die" represents the chip, "Si THK" represents the stop layer (silicon nitride-a high dielectric constant material), "Passivation" represents the passivation layer, "Cu-pillar" represents the copper pillar, and "epoxy molding compound (EMC)" represents the epoxy molding compound. Many previous studies [1][2][3][4][5][6][7][8][9][10][11][12][13][14] have focused on evaluating whether changes in the structural design or material selection of the packaging can reduce the amount of wafer warpage caused by the thermal process in fan-out wafer-level packaging (FOWLP). Analyzing the effect of material properties on wafer warpage is one of the important ways of understanding warpage factors and effectively improving wafer warpage.…”

Section: Introductionmentioning

confidence: 99%

Exploring the Influence of Material Properties of Epoxy Molding Compound on Wafer Warpage in Fan-Out Wafer-Level Packaging

2023

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This study investigated the impact of material properties of epoxy molding compounds on wafer warpage in fan-out wafer-level packaging. As there is currently a lack of comprehensive discussion on the various material property parameters of EMC materials, it is essential to identify the critical influencing factors and quantify the effects of each parameter on wafer warpage. The material properties include Young’s modulus of the epoxy molding compound before and after the glass transition temperature (Tg) range of 25–35 °C (EL) and 235–260 °C (EH), coefficient of thermal expansion (α1, α2), and the temperature change (∆T) between EL and EH. Results show that, within the range of extreme values of material properties, EL and α1 are the critical factors that affect wafer warpage during the decarrier process in fan-out packaging. α1 has a more significant impact on wafer warpage compared with EL. EH, α2, Tg, and ∆T have little influence on wafer warpage. Additionally, the study identified the optimized material property of the epoxy molding compound that can reduce the maximum wafer warpage in the X and Y directions from initial values of 7.34 mm and 7.189 mm to 0.545 mm and 0.45 mm, respectively, resulting in a reduction of wafer warpage of 92.58% (X direction) and 93.74% (Y direction). Thus, this study proposes an approach for evaluating the impact of material properties of epoxy molding compounds on wafer warpage in fan-out wafer-level packaging. The approach aims to address the issue of excessive wafer warpage due to material variation and to provide criteria for selecting appropriate epoxy molding compounds to enhance process yield in packaging production lines.

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Reliability Assessment of Thermocompressed Epoxy Molding Compound through Glass via Interposer Architecture by the Submodeling Simulation Approach

Cited by 6 publications

References 34 publications

Layout Dependence Stress Investigation in through Glass via Interposer Architecture Using a Submodeling Simulation Technique and a Factorial Design Approach

Layout Dependence Stress Investigation in through Glass via Interposer Architecture Using a Submodeling Simulation Technique and a Factorial Design Approach

Improvement of catheter tip morphology by mold material used for tip‐forming process

Exploring the Influence of Material Properties of Epoxy Molding Compound on Wafer Warpage in Fan-Out Wafer-Level Packaging

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