2022
DOI: 10.1108/ssmt-03-2022-0017
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Numerical modelling of the delamination in multi-layered ceramic capacitor during the thermal reflow process

Abstract: Purpose This paper aims to study the interfacial delamination found in the boundary of the copper/copper-epoxy layers of a multi-layer ceramic capacitor. Design/methodology/approach The thermal reflow process of the capacitor assembly and the crack propagation from the initial micro voids presented in the boundary, and later manifested into delamination, were numerically simulated. Besides, the cross section of the capacitor assembly was inspected for delamination cracks and voids using a scanning electronic… Show more

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Cited by 4 publications
(6 citation statements)
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“…After the reflow process and when the heat is no longer applied, these deformations would be reversed, but at different rates for each layer. This thermal mismatch of both copper-electrode and copper-epoxy layers leads to the cracking (Ng et al , 2022b), manifested as a gap, due to the uneven thermal expansions between adjacent copper-electrode and copper-epoxy layers as shown in Figure 11. In the absence of the copper-epoxy layer, the adjacent copper-electrode layer and nickel layer would undergo similar deformations, as their CTEs are 14.8 ppm/°C and 12.8 ppm/°C, respectively.…”
Section: Resultsmentioning
confidence: 99%
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“…After the reflow process and when the heat is no longer applied, these deformations would be reversed, but at different rates for each layer. This thermal mismatch of both copper-electrode and copper-epoxy layers leads to the cracking (Ng et al , 2022b), manifested as a gap, due to the uneven thermal expansions between adjacent copper-electrode and copper-epoxy layers as shown in Figure 11. In the absence of the copper-epoxy layer, the adjacent copper-electrode layer and nickel layer would undergo similar deformations, as their CTEs are 14.8 ppm/°C and 12.8 ppm/°C, respectively.…”
Section: Resultsmentioning
confidence: 99%
“…To the best of the authors’ knowledge, previous studies by Lee and Yoon have investigated the reliability of soft-termination MLCCs with additional ag-epoxy (Lee and Yoon, 2022). In addition, Ng has conducted numerical modelling of delamination at the copper/copper-epoxy layers of MLCCs during the reflow process (Ng et al , 2022a). However, the work was conducted without focusing on moisture-induced crack propagation in MLCC.…”
Section: Introductionmentioning
confidence: 99%
“…Various researchers have applied numerical and experimental fracture mechanics techniques to examine the defect growth behavior of soldered electronic packages in a thermal environment. Fatigue fracture behavior in various copper/lead-free solder junctions that had been thermally aged is examined in Zhang et al (2010), Ng et al (2022). In Hofmeister et al (2008), fracture mechanics was used to study the propagation of initial voids and cracks to establish the defects growth phenomena in integrated circuit (IC) components and solder joints.…”
Section: Introductionmentioning
confidence: 99%
“…Despite the notable contributions in the literature on fracture mechanics of electronic packages, a few research studies (Ahmar and Wiese, 2017; Ng et al , 2022; Bachok et al , 2023; Jin Kim et al , 2007; Tao et al , 2017; Apalowo et al , 2023) exist on the experimental study of thermally reflowed ceramic capacitors. Furthermore, a limited number of works (Ng et al , 2022; Bachok et al , 2023; Apalowo et al , 2023) considered the fracture growth phenomenon during thermal reflow of soft-termination MLCCs. Also, only one (Apalowo et al , 2023) of the limited studies subjected the soft-termination MLCC to multiple (accelerated) thermal reflow.…”
Section: Introductionmentioning
confidence: 99%
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