Your search keyword '"Huib Scholten"' showing total 5 results

1. Exploring the process-microstructure-thermal properties relationship of resin-reinforced Ag sintering material for high-power applications via 3D FIB-SEM nanotomography

Author

Xiao Hu, Henry Antony Martin, René Poelma, Jianlin Huang, Hans van Rijckevorsel, Huib Scholten, Edsger Smits, Willem D. van Driel, and Guoqi Zhang

Subjects

3D FIB-SEM nanotomography, Geometric tortuosity, Effective thermal conductivity, Transient thermal impedance, Thermal percolation phenomenon, High-power application, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Resin-reinforced Ag sintering materials represent a promising solution for die-attach applications in high-power devices requiring enhanced reliability and heat dissipation. However, the presence of resin and intricate microstructure poses challenges to its thermal performance, and improvement strategies remain unclear. This work utilizes 3D FIB-SEM nanotomography to reconstruct the microstructure of this material under various process conditions. The analysis reveals that, even with an Ag volume fraction as low as 47.3%, Ag particles form a robust 3D network. Geometric tortuosity quantifies the effect of different sintering conditions on the Ag particle network in all spatial directions. Effective thermal conductivity is simulated based on realistic microstructure models. Results show a significant negative correlation between tortuosity and effective thermal conductivity. Increasing sintering temperature in Model B notably reduces tortuosity and enhances effective thermal conductivity. Sensitivity analysis underscores the dominant role of Ag volume fraction in regulating effective thermal conductivity. Finally, transient thermal impedance measurement of this material as a thin die-attach layer in actual high-power devices demonstrated its application potential. This article strives to explore the relationship between process, microstructure, and thermal properties of this material to provide a reference for further development.

Published

2024

2. FEM modelling of porosity in Ag sintering die attach for RF power applications

Author

Mario de Vaan, Frank de Bruijn, An Xiao, Jianlin Huang, and Huib Scholten

Subjects

Void (astronomy), Materials science, Ultimate tensile strength, Shear stress, Sintering, Direct shear test, Temperature cycling, Composite material, Porosity, Porous medium

Abstract

In this paper, a modified Gurson model was developed to simulate the mechanical behavior of silver sintered materials in which the porosity is ranging from 5% to 40%. The effect of shear stress, void size, and porosity- and temperature-dependent elastic properties of the porous materials were added into the standard Gurson model. Tensile and shear test simulations showed that the proposed Gurson model is capable in describing the mechanical behaviors of the Ag sintered specimen. The thermal cycling test (TMCL) simulations further showed the capability of the proposed Gurson model in the design of RF power applications.

Published

2018

3. Effect of high temperature aging on reliability of automotive electronics

Author

R. Faria, W.D. van Driel, L. Goumans, Huib Scholten, F.F. Wan, Z.Y. Shou, and Daoguo Yang

Subjects

Materials science, Modulus, Molding (process), Condensed Matter Physics, Microstructure, Atomic and Molecular Physics, and Optics, Thermal expansion, Finite element method, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Stress (mechanics), Electrical and Electronic Engineering, Composite material, Safety, Risk, Reliability and Quality, Material properties, Shrinkage

Abstract

In this paper, an investigation on the effect of high temperature aging on the thermomechanical properties, microstructure of the molding compounds and the reliability issues of the packages is presented. Experimental characterizations of aging effect on the packaging materials and the package were carried out. DMA, TMA and TGA were used to measure the moduli, coefficients of thermal expansion (CTE), and the shrinkage induced by the aging process. Construction analysis was performed to examine the aging effect on the microstructure of the aged samples. It is found that aging has significant influence on the rubbery modulus, the glass transition temperature (Tg) and the strength. Aging-induced shrinkage was also found. Oxidation is believed to be one of the main mechanisms for the degradation of the material properties. Finite element modeling is applied to investigate effect of aging on the reliability of the packages. An aging-dependent elastic model has been established to describe the material property evolution caused by aging. 2D finite element models were established to simulate the impact of the aging effect on the stress/strain of the package. Aging-induced shrinkage was also considered in the model, which was applied to the surface layer. The modeling results indicate that the aging of the compounds has a significant impact on the stress/strain status in the package. And the aging-induced shrinkage cannot be simply neglected. Further research work on the experimental aspects and improvement of the aging-related material models are needed.

Published

2011

4. Advanced reliability study on high temperature automotive electronics

Author

Huib Scholten, Dongjing Liu, Daoguo Yang, W.D. van Driel, R. Faria, and L. Goumans

Subjects

Reliability (semiconductor), Materials science, Molding (process), Dynamic mechanical analysis, Composite material, Microstructure, Material properties, Thermal analysis, Automotive electronics, Shrinkage

Abstract

To ensure high reliability for advanced automotive electronics, investigation and understanding on the failure mechanisms under harsh conditions are needed. New methods and technologies for improved reliability and increased lifetime should be developed. In this paper, an investigation on the effect of high temperature aging on the thermomechanical properties, microstructure of the molding compounds and the reliability issues of the packages is presented. Experimental characterizations of aging effect on the packaging materials and the package were carried out. DMA, TMA and TGA were used to measure the moduli, coefficients of thermal expansion (CTE), and the shrinkage induced by the aging process. Construction analysis was performed to examine the aging effect on the microstructure of the aged samples. It is found that aging has significant influence on the rubbery modulus, the glass transition temperature (Tg) and the strength. Aging-induced shrinkage was also found. Oxidation is believed to be one of the main mechanisms for the degradation of the material properties.

Published

2010

5. Virtual thermo-mechanical prototyping for high-temperature-application microelectronics

Author

L. Goumans, Daoguo Yang, R. Faria, Huib Scholten, and W.D. van Driel

Subjects

Stress (mechanics), Materials science, business.industry, Electronic packaging, Modulus, Microelectronics, Composite material, Material properties, Microstructure, business, Thermal expansion, Shrinkage

Abstract

In this paper, an investigation on the reliability issues of the packages for high temperature applications is presented. First, experimental characterizations of aging effect on the packaging materials and the package were carried out. DMA, TMA and TGA were used to measure the moduli, coefficients of thermal expansion (CTE), and the shrinkage induced by the aging process. Construction analysis was performed to examine the aging effect on the microstructure of the aged samples. It is found that aging has significant influence on the rubbery modulus, the glass transition temperature (T g ) and the strength. Oxidation is believed to be one of the main mechanisms for the degradation of the material properties. In order to reduce cost and time-to-market, thermo-mechanical virtual prototyping is applied to investigate effect of aging on the reliability of the high temperature application packages. An aging-dependent elastic model has been established to describe the material property evolution caused by aging. 3D Finite Element models were established to simulate the impact of the aging effect on the stress/strain of the package. Aging-induced shrinkage was also considered in the model, which was applied to the surface layer. The modeling results indicate that the aging of the compounds have a significant impact on the stress/strain status in the package. And the aging-induced shrinkage can not be simply neglected. Further research work on the experimental aspects and improvement of the aging-related material models are needed.

Published

2010