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Coexistent improvement of thermal and mechanical performance at Si/Cu joint by thickness-controlled Sn-Ag bond layer

Abstract

In this study, sound Si-Cu joints with high thermal conductivity and mechanical property were achieved at 260 degrees C with thickness-controlled Sn-Ag bond layer. The microstructure evolution, thermal and mechanical properties were proposed systematically. The bond layer was fabricated by micro electroforming technology to precisely control the thickness and improve the bond ability. The electroformed Ag layer could protect the sputtered Cu film and restrict the diffusion of Cu elements, which could decrease the residual stress and remove the interface defects. At the joints, the electroformed Sn layer was consumed to form Ag3Sn and Cu6Sn5 inter-metallic compounds. The thermal conductivity and shear strength both increased firstly and then decreased with the thickness of bond layer increasing. The highest thermal conductivity of 283.21 W/(m.K) and shear strength of 88.74 MPa were achieved synchronous with 15-mu m-thickness Sn-Ag bond layers, which were attributed to the reduction of the interface stress and elimination of interfacial defects. This technology had potential to be applied in the microelectronic heat dissipation at the future.

article Article

date_range 2023

language English

link Link of the paper

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Zhang Yanxin

Zhu Yuan

Cai Han

Li Yahui

Song Jungsuk

Sun Yunna

Yang Zhuoqing

Ding Guifu

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Featured Keywords

Bond layer

Thermal conductivity

Microstructure

Intermetallic compounds

Solder

Sn-Ag

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Performance evaluation of mortar with ground and thermo-activated recycled concrete cement

Abstract

The main objective of this study was to examine the combined effect of ground recycled concrete cement (GRC) and thermo-activated recycled concrete cement (TARC) on properties of mortar. The physical, chemical and microstructural tests were conducted to characterize GRC and TARC before mortar mixtures were produced. The microscopic morphology of GRC and TARC revealed uneven edges and a rough surface that is slightly porous. The GRC and TARC powders were used to replace cement in the range of 0-50% at increments of 10% by volume. The fresh, mechanical, microstructure, and durability characteristics of mortar were tested for different proportion of GRC and TARC as partial replacement of cement. The usage of GRC and TARC decreases the workability of mortar marginally. However, the mechanical performance of the mortar mixtures showed an increasing trend when GRC and TARC share increases in the mixture. Predominantly, compressive strength, bulk density, and ultrasonic pulse velocity (UPV) have all been increased by as much as 20% cement replacement. Furthermore, the incorporation of GRC and TARC enhances the mortar’s durability properties. The microstructure analysis reveals that 20% replacement (GT20) mix has superior structural compactness. In general, partially substitution of GRC and TARC by ordinary Portland cement improves several characteristics of mortar. This will help solve the most prevalent problems that concrete produces, including the high embedded carbon dioxide creation, the high resource usage, and the high waste generation after demolition.

article Article

date_range 2024

language English

link Link of the paper

Compressive Strength

GT0-GT50 (xlsx)